EarthCube Data Discovery Hub: Enhancing, Curating and Finding Data across Multiple Geoscience Data Sources.

NASA Astrophysics Data System (ADS)

Zaslavsky, I.; Valentine, D.; Richard, S. M.; Gupta, A.; Meier, O.; Peucker-Ehrenbrink, B.; Hudman, G.; Stocks, K. I.; Hsu, L.; Whitenack, T.; Grethe, J. S.; Ozyurt, I. B.

2017-12-01

EarthCube Data Discovery Hub (DDH) is an EarthCube Building Block project using technologies developed in CINERGI (Community Inventory of EarthCube Resources for Geoscience Interoperability) to enable geoscience users to explore a growing portfolio of EarthCube-created and other geoscience-related resources. Over 1 million metadata records are available for discovery through the project portal (cinergi.sdsc.edu). These records are retrieved from data facilities, including federal, state and academic sources, or contributed by geoscientists through workshops, surveys, or other channels. CINERGI metadata augmentation pipeline components 1) provide semantic enhancement based on a large ontology of geoscience terms, using text analytics to generate keywords with references to ontology classes, 2) add spatial extents based on place names found in the metadata record, and 3) add organization identifiers to the metadata. The records are indexed and can be searched via a web portal and standard search APIs. The added metadata content improves discoverability and interoperability of the registered resources. Specifically, the addition of ontology-anchored keywords enables faceted browsing and lets users navigate to datasets related by variables measured, equipment used, science domain, processes described, geospatial features studied, and other dataset characteristics that are generated by the pipeline. DDH also lets data curators access and edit the automatically generated metadata records using the CINERGI metadata editor, accept or reject the enhanced metadata content, and consider it in updating their metadata descriptions. We consider several complex data discovery workflows, in environmental seismology (quantifying sediment and water fluxes using seismic data), marine biology (determining available temperature, location, weather and bleaching characteristics of coral reefs related to measurements in a given coral reef survey), and river geochemistry (discovering observations relevant to geochemical measurements outside the tidal zone, given specific discharge conditions).

OERL: A Tool For Geoscience Education Evaluators

NASA Astrophysics Data System (ADS)

Zalles, D. R.

2002-12-01

The Online Evaluation Resource Library (OERL) is a Web-based set of resources for improving the evaluation of projects funded by the Directorate for Education and Human Resources (EHR) of the National Science Foundation (NSF). OERL provides prospective project developers and evaluators with material that they can use to design, conduct, document, and review evaluations. OERL helps evaluators tackle the challenges of seeing if a project is meeting its implementation and outcome-related goals. Within OERL is a collection of exemplary plans, instruments, and reports from evaluations of EHR-funded projects in the geosciences and in other areas of science and mathematics. In addition, OERL contains criteria about good evaluation practices, professional development modules about evaluation design and questionnaire development, a dictionary of key evaluation terms, and links to evaluation standards. Scenarios illustrate how the resources can be used or adapted. Currently housed in OERL are 137 instruments, and full or excerpted versions of 38 plans and 60 reports. 143 science and math projects have contributed to the collection so far. OERL's search tool permits the launching of precise searches based on key attributes of resources such as their subject area and the name of the sponsoring university or research institute. OERL's goals are to 1) meet the needs for continuous professional development of evaluators and principal investigators, 2) complement traditional vehicles of learning about evaluation, 3) utilize the affordances of current technologies (e.g., Web-based digital libraries, relational databases, and electronic performance support systems) for improving evaluation practice, 4) provide anytime/anyplace access to update-able resources that support evaluators' needs, and 5) provide a forum by which professionals can interact on evaluation issues and practices. Geoscientists can search the collection of resources from geoscience education projects that have been funded by NSF to carry out curriculum development, teacher education, faculty development, and increased access, retention, and preparation of under-represented student populations in science. Over the next two years, additional plans, instruments, and reports from other projects will be added to the OERL collection. Also to be added are more professional development modules and online coaches for constructing key evaluation documents. The presentation overviews the structure of OERL, describes some of the geoscience projects in the collection, and provides some examples of how its resources can be used and adapted for other geoscience education evaluations.

Training Teachers to Use Technology and Inquiry-based Learning Practices in the Geosciences through an Industry-University Partnership

NASA Astrophysics Data System (ADS)

McNeal, K.; Buell, R.; Eiland, L.

2009-12-01

Teacher professional development centered about the Geosciences is necessary in order to train K-12 teachers about this science field and to effectively educate K-12 students about Earth processes. The partnership of industries, universities, and K-12 schools is a collaborative pathway to support these efforts by providing teachers access to technology, inquiry-based learning, and authentic field experiences within the Geosciences context. This research presents the results of Project SMARTER (Science and Mathematics Advancement and Reform utilizing Technology and Enhanced Resources), a co-lead industry-university partnership and teacher professional development workshop program that focused on technology and inquiry-based learning in the Geosciences. The workshop included fifteen teachers from five distressed counties in Mississippi as defined by the Appalachian Regional Commission. Three (one science, once math, one technology) 7-12 grade teachers were selected from each school district and worked together during activities as a team to foster a cooperative learning experience. The two week workshop trained teachers on the use of a variety of technologies including: Vernier Probes and software, TI-calculators and presenter, Mimio Boards, GPS receivers, Google Earth, Excel, PowerPoint, projectors, and the use of historic geologic datasets. Furthermore, teachers were trained on proper field collection techniques, the use of Hach Kits and field probes, and the interpretation of geologic data. Each daily program incorporated the use of technology-rich and inquiry-based activities into one of the five Earth spheres: atmosphere, lithosphere, biosphere, hydrosphere, and anthrosphere. Results from the pre-post technology attitude survey showed that participating teachers significantly (p < 0.05) increased their confidence level in using technology. Furthermore, all participants self-reflected that the workshop both increased their interest in the Geosciences and their plans to integrate technology in future classroom activities. Qualitative responses from daily feedback forms and journal entries indicated that participating teachers were enthusiastic about inquiry-, technology-, and field-based learning activities and were willing to incorporate cross-discipline lesson plans. Evaluation of final lesson plans developed by the teachers during the workshop combined with follow-up classroom visits illustrated that the teachers appropriately developed classroom lessons to incorporate inquiry and technology and that they successfully implemented these lesson plans in their own classroom as a direct result of participating in workshop activities.

Facilitating Classroom Innovation in the Geosciences Through the NSF Transforming Undergraduate Education in Science, Technology, Engineering, and Mathematics (TUES) Program

NASA Astrophysics Data System (ADS)

Singer, J.; Ryan, J. G.

2012-12-01

The Transforming Undergraduate Education in Science, Technology, Engineering, and Mathematics (TUES) program seeks to improve the quality of science, technology, engineering, and mathematics (STEM) education for all undergraduate students. Activities supported by the TUES program include the creation, adaptation, and dissemination of learning materials and teaching strategies, development of faculty expertise, implementation of educational innovations, and research on STEM teaching and learning. The TUES program especially encourages projects that have the potential to transform undergraduate STEM education and active dissemination and building a community of users are critical components of TUES projects. To raise awareness about the TUES program and increase both the quality and quantity of proposals submitted by geoscientists to the program, information sessions and proposal writing retreats are being conducted. Digital resources developed especially for the geosciences community are available at www.buffalostate.edu/RTUGeoEd to share information about the TUES program and the many ways this NSF program supports innovation in geoscience education. This presentation also addresses identified impediments to submitting a TUES proposal and strategies for overcoming reasons discouraging geoscientists from preparing a proposal and/or resubmitting a declined proposal.

Research Staff | Geothermal Technologies | NREL

Science.gov Websites

Position Email Phone Akar, Sertac Energy Analyst - Geothermal Sertac.Akar@nrel.gov 303-275-3725 Augustine -Geoscience Kate Young joined NREL in 2008. She has worked on analysis of geothermal exploration, drilling ) Toolkit, the Geothermal Resource Portfolio Optimization and Reporting Technique (GeoRePORT), and the

New Resources on the Building Strong Geoscience Departments Website

NASA Astrophysics Data System (ADS)

Ormand, C. J.; Manduca, C. A.; MacDonald, H.

2009-12-01

The Building Strong Geoscience Departments program aims to foster communication and sharing among geoscience departments in order to allow for rapid dissemination of strong ideas and approaches. Sponsored by NAGT, AGI, AGU, and GSA, the project has developed a rich set of web resources and offered workshops on high-interest topics, such as recruiting students, curriculum development, and program assessment. The Building Strong Geoscience Departments website has a growing collection of resources, drawn from workshop discussions and presentations, showcasing how geoscience departments approach curriculum revision, student recruitment, and program assessment. Recruitment resources consist of specific examples of a wide variety of successful approaches to student recruitment from departments at a wide array of institutions. Curricular feature pages framing the process of curriculum development or revision and a collection of dozens of geoscience curricula, searchable by degree program name. Each curriculum in the collection includes a diagram of the course sequence and structure. Program assessment resources include a collection of assessment instruments, ranging from alumni surveys and student exit interviews to course evaluations and rubrics for assessing student work, and a collection of assessment planning documents, ranging from mission and vision statements through student learning goals and outcomes statements to departmental assessment plans and guidelines for external reviews. These recruitment strategies, curricula, and assessment instruments and documents have been contributed by the geoscience community. In addition, we are developing a collection of case studies of individual departments, highlighting challenges they have faced and the strategies they have used to successfully overcome those challenges. We welcome additional contributions to all of these collections. These online resources support the Building Strong Geoscience Departments Visiting Workshop program, which we launched in the fall of 2009.

Using the Geoscience Literacy Frameworks and Educational Technologies to Promote Science Literacy in Non-science Major Undergraduates

NASA Astrophysics Data System (ADS)

Carley, S.; Tuddenham, P.; Bishop, K. O.

2008-12-01

In recent years several geoscience communities have been developing ocean, climate, atmosphere and earth science literacy frameworks as enhancements to the National Science Education Standards content standards. Like the older content standards these new geoscience literacy frameworks have focused on K-12 education although they are also intended for informal education and general public audiences. These geoscience literacy frameworks potentially provide a more integrated and less abstract approach to science literacy that may be more suitable for non-science major students that are not pursuing careers in science research or education. They provide a natural link to contemporary environmental issues - e.g., climate change, resource depletion, species and habitat loss, natural hazards, pollution, development of renewable energy, material recycling. The College of Exploration is an education research non-profit that has provided process and technical support for the development of most of these geoscience literacy frameworks. It has a unique perspective on their development. In the last ten years it has also gained considerable national and international expertise in facilitating web-based workshops that support in-depth conversations among educators and working scientists/researchers on important science topics. These workshops have been of enormous value to educators working in K-12, 4-year institutions and community colleges. How can these geoscience literacy frameworks promote more collaborative inquiry-based learning that enhances the appreciation of scientific thinking by non-majors? How can web- and mobile-based education technologies transform the undergraduate non-major survey course into a place where learners begin their passion for science literacy rather than end it? How do we assess science literacy in students and citizens?

The National Aeronautics and Space Administration interdisciplinary studies in space technology at the University of Kansas

NASA Technical Reports Server (NTRS)

Barr, B. G.

1974-01-01

A broad range of research projects contained in a cooperative space technology program at the University of Kansas are reported as they relate to the following three areas of interdisciplinary interest: (1) remote sensing of earth resources; (2) stability and control of light and general aviation aircraft; and (3) the vibrational response characteristics of aeronautical and space vehicles. Details of specific research efforts are given under their appropriate departments, among which are aerospace engineering, chemical and petroleum engineering, environmental health, water resources, the remote sensing laboratory, and geoscience applications studies.

NativeView: Our Land, Our People, Our Future

NASA Astrophysics Data System (ADS)

Bennett, T.

2006-05-01

The objective of this discussion is to (1) discuss the chasm between the breadth of Tribal land and resource to be sustained compared to the finite number of Tribal people trained in the sciences; (2) illustrate the need for integrating scientific knowledge with cultural knowledge; and (3) discuss the emergence of NativeView as Tribal College (TCUs) initiative leading the integration of geoscience and geospatial technology (GIS, Remote Sensing) with cultural knowledge to meet the growing needs of indigenous communities. It's about our land, our people and the need for highly trained individuals to sustainable and manage our resources for the future. There is a tremendous gap between total acreage of land owned or managed and the level of education obtained by indigenous people. In the United States today, American Indians and Alaskan Natives account for less than one percent of the total population, yet are responsible for more than five percent of the total land area. In North Dakota, there are over 54 thousand American Indians responsible for more than 3.8 million acres of Tribal Land. In contrast, less than 15 percent of indigenous people finish a Bachelor's degree of any kind and far fewer finish a science degree that would help them become more effective and responsible land managers. This poses an important dilemma. How will the Tribes meet (1) the resource needs of a growing population, (2) the demand for a skilled workforce, and (3) resource management goals in ways that contribute to Tribal infrastructure and equate to sustainable resource management? The integration of geoscience and geospatial technologies into the curriculum of Tribal Colleges (TCU's) has quietly emerged as one of the leading initiatives across Indian Country. These skills are widely recognized as a vehicle to empower our constituents in the sciences, in the cultural values and the traditional land ethic that defines us as a people. NativeView has taken the lead in working with the Tribes, TCUs and other partners to create cadres of indigenous professionals that possess skills in geoscience and geospatial technologies that will manage Tribal resources in scientifically sound, culturally relevant ways. Preliminary results suggest that developing strength-based collaborations that create an environment of investment and ownership by all Indian and non-Indian participants proves an effective model for meeting long- term goals. A number of these projects and the mechanisms that define the successful collaborations will be illustrated.

Learning from One Another: On-line Resources for Geoscience Departments

NASA Astrophysics Data System (ADS)

Manduca, C. A.; MacDonald, R. H.; Feiss, P. G.; Richardson, R. R.; Ormand, C.

2007-12-01

Geoscience departments are facing times of great change, bringing both opportunity and challenge. While each department is unique with its own mission, institutional setting, strengths and assets, they share much in common and are all much better positioned to maximize gains and minimize losses if they are well informed of the experiences of other geoscience departments. To this end, over the past four years the Building Strong Geoscience Departments project has offered workshops and sessions at professional society meetings to foster sharing and discussion among geoscience departments in the United States and Canada. Topics that have sparked extended discussion include: Where are the geosciences headed from the standpoints of scientific research and employment? How are departments responding to new interdisciplinary opportunities in research and teaching? What are the threats and opportunities facing geoscience departments nationwide? How are departments recruiting students and faculty? What do geoscience department programs look like both from the standpoint of curriculum and activities beyond the curriculum? How do geoscience programs prepare students for professional careers? What makes a department strong in the eyes of the faculty or the eyes of the institution? This rich discussion has included voices from community colleges, four year colleges and universities, comprehensive and research universities, and minority serving institutions. Participants agree that these discussions have helped them in thinking strategically about their own departments, have provided valuable ideas and resources, and have lead to changes in their program and activities. A central aspect of the project has been the development of a website that captures the information shared at these meetings and provides resources that support departments in exploring these topics. The website (serc.carleton.edu/departments) is a community resource and all departments are invited to both learn from and contribute to its collections.

Using Web 2.0 technologies to recruit the next generation of talent to the geoscience workforce

NASA Astrophysics Data System (ADS)

Martinez, C. M.; Keane, C. M.

2009-12-01

The GeoConnection Network is an integrated set of social networking, media sharing and communication Web 2.0 applications designed to engage students in thinking about careers in the geosciences. Developed by the American Geological Institute (AGI), GeoConnection links practicing and prospective geoscientists in an informal setting to share information about the geoscience profession, including student and career opportunities, current events, and future trends in the geosciences. The network includes a Facebook fan page, YouTube Channel, Twitter account and GeoSpectrum blog, with the goal of helping science organizations and departments recruit future talent to the geoscience workforce. On the social-networking platform, Facebook, the GeoConnection page is a forum for students and early career geoscientists to tune in what's going on in the geoscience community, to meet geoscience professionals, and to find innovative career ideas. Early analysis of the page’s participants indicates that the network is reaching its intended audience, with more than two thirds of “fans” participating in the page falling in the 18-34 age range. Twenty-seven percent of these are college-aged, or 18-24 years old. An additional 20% of the page’s fans are over age 45, providing students with access to seasoned geoscientists working in a variety of professions. GeoConnection’s YouTube Channel includes video resources for students on educational pathways and career choices. Videos on the channel have received more than 60,000 views collectively. AGI is currently evaluating its use of the GeoConnection Network and Web 2.0-based student engagement strategies through direct surveys to students and university departments, in order to improve its offerings and to maximize its use of resources. The challenge for the GeoConnection Network in its quest to attract the best and brightest new talent to the geosciences is staying current within the ever-changing landscape of online communications. Reports show that participation in social-networking media among young people ages 16-24 has dropped (eg. Istrategy Labs, 2009, Ofcom, 2009) however, internet use among younger generations is high. Geoscience organizations must identify and participate in new online communications trends in order to continue to reach students.

Bridging Learning Communities Through Experiential Learning with GIST: 2Y College Experience

NASA Astrophysics Data System (ADS)

Sorey, N.; Phillips, C. D.

2017-12-01

This study reviews successes of community engagement through experiential learning with GIST across academic disciplines that leverage topics with technology and community relationships throughout a two-year campus and the community at large. This approach allowed for a diversification of populations reached through college student engagement and community outreach efforts. Technological frameworks and development of best practice resources to support students and faculty were shown to increase the capacity for undergraduate research experiences, K12 short course offerings during the summer, and the formation of a STEM-focused student organization. The RSO has participated in activities that include educational technology development, participating in the growth and development of the area's maker movement community, and geoscience outreach and education. Development of the program thus far and lessons learned have resulted in a proposal for an areal-based informal pathway linking the K12 community to area colleges by integrating geoscience outreach with GIST through the maker movement.

Inquiring with Geoscience Datasets: Instruction and Assessment

NASA Astrophysics Data System (ADS)

Zalles, D.; Quellmalz, E.; Gobert, J.

2005-12-01

This session will describe a new NSF-funded project in Geoscience education, Inquiring with Geoscience Data Sets. The goals of the project are to (1) Study the impacts on student learning of Web-based supplementary curriculum modules that engage secondary-level students in inquiry projects addressing important geoscience problems using an Earth System Science approach. Students will use technologies to access real data sets in the geosciences and to interpret, analyze, and communicate findings based on the data sets. The standards addressed will include geoscience concepts, inquiry abilities in NSES and Benchmarks for Science Literacy, data literacy, NCTM standards, and 21st-century skills and technology proficiencies (NETTS/ISTE). (2) Develop design principles, specification templates, and prototype exemplars for technology-based performance assessments that provide evidence of students' geoscientific knowledge and inquiry skills (including data literacy skills) and students' ability to access, use, analyze, and interpret technology-based geoscience data sets. (3) Develop scenarios based on the specification templates that describe curriculum modules and performance assessments that could be developed for other Earth Science standards and curriculum programs. Also to be described in the session are the project's efforts to differentiate among the dimensions of data literacy and scientific inquiry that are relevant for the geoscience discplines, and how recognition and awareness of the differences can be effectively channelled for the betterment of geoscience education.

The IUGS Task Group on Global Geoscience Professionalism - promoting professional skills professionalism in the teaching, research and application of geoscience for the protection and education of the public

NASA Astrophysics Data System (ADS)

Allington, Ruth; Fernandez-Fuentes, Isabel

2013-04-01

A new IUGS Task Group entitled the Task Group on Global Geoscience Professionalism was formed in 2012 and launched at a symposium at the 341GC in Brisbane on strengthening communication between fundamental and applied geosciences and between geoscientists and public. The Task Group aims to ensure that the international geoscience community is engaged in a transformation of its profession so as to embed the need for a professional skills base alongside technical and scientific skills and expertise, within a sound ethical framework in all arenas of geoscience practice. This needs to be established during training and education and reinforced as CPD throughout a career in geoscience as part of ensuring public safety and effective communication of geoscience concepts to the public. The specific objective of the Task Group on Global Geoscience Professionalism that is relevant to this poster session is: • To facilitate a more 'joined up' geoscience community fostering better appreciation by academics and teachers of the professional skills that geoscientists need in the workplace, and facilitate better communication between academic and applied communities leading to more effective application of research findings and technology to applied practitioners and development of research programmes that truly address urgent issues. Other Task Group objectives are: • To provide a specific international forum for discussion of matters of common concern and interest among geoscientists and geoscientific organizations involved in professional affairs, at the local, national and international level; • To act as a resource to IUGS on professional affairs in the geosciences as they may influence and impact "Earth Science for the Global Community" in general - both now and in the future; • To offer and provide leadership and knowledge transfer services to countries and geoscientist communities around the world seeking to introduce systems of professional governance and self-regulation in the Earth sciences; • To provide geoscientists in all areas of professional practice and at all stages of their careers with practical guidance and support on professional matters; • To continue and increase over time the provision of symposia and technical sessions to allow for exchange and knowledge transfer at IGCs and other events for those involved in, and impacted by, the evolution of professionalism in the geosciences. • To act as a resource to members of IUGS, and others, of material and speakers to present to geoscience groups - in particular young Earth scientists - around the world on professional practice and registration matters (including geoscience practice standards and guidelines, and reporting standards, codes of ethics and conduct, and professional registration.) The sponsors of the new TG are: • European Federation of Geologists (EFG) • Geoscientists Canada • American Institute of Professional Geologists (AIPG) • Australian Institute of Geoscientists (AIG) • South African Council for Natural Scientific Professions (SACNSP) • El Colegio de Geólogos de Bolivia (College of Geologists of Bolivia)

The use of Web-based GIS data technologies in the construction of geoscience instructional materials: examples from the MARGINS Data in the Classroom project

NASA Astrophysics Data System (ADS)

Ryan, J. G.; McIlrath, J. A.

2008-12-01

Web-accessible geospatial information system (GIS) technologies have advanced in concert with an expansion of data resources that can be accessed and used by researchers, educators and students. These resources facilitate the development of data-rich instructional resources and activities that can be used to transition seamlessly into undergraduate research projects. MARGINS Data in the Classroom (http://serc.carleton.edu/ margins/index.html) seeks to engage MARGINS researchers and educators in using the images, datasets, and visualizations produced by NSF-MARGINS Program-funded research and related efforts to create Web-deliverable instructional materials for use in undergraduate-level geoscience courses (MARGINS Mini-Lessons). MARGINS science data is managed by the Marine Geosciences Data System (MGDS), and these and all other MGDS-hosted data can be accessed, manipulated and visualized using GeoMapApp (www.geomapapp.org; Carbotte et al, 2004), a freely available geographic information system focused on the marine environment. Both "packaged" MGDS datasets (i.e., global earthquake foci, volcanoes, bathymetry) and "raw" data (seismic surveys, magnetics, gravity) are accessible via GeoMapApp, with WFS linkages to other resources (geodesy from UNAVCO; seismic profiles from IRIS; geochemical and drillsite data from EarthChem, IODP, and others), permitting the comprehensive characterization of many regions of the ocean basins. Geospatially controlled datasets can be imported into GeoMapApp visualizations, and these visualizations can be exported into Google Earth as .kmz image files. Many of the MARGINS Mini-Lessons thus far produced use (or have studentss use the varied capabilities of GeoMapApp (i.e., constructing topographic profiles, overlaying varied geophysical and bathymetric datasets, characterizing geochemical data). These materials are available for use and testing from the project webpage (http://serc.carleton.edu/margins/). Classroom testing and assessment of the Mini- Lessons begins this Fall.

Development of the Virginia Tech Department of Geosciences MEDL-CMC

NASA Astrophysics Data System (ADS)

Glesener, G. B.

2016-12-01

In 2015 the Virginia Tech Department of Geosciences took a leading role in increasing the level of support for Geoscience instructors by investing in the development of the Geosciences Modeling and Educational Demonstrations Laboratory Curriculum Materials Center (MEDL-CMC). The MEDL-CMC is an innovative curriculum materials center designed to foster new collaborative teaching and learning environments by providing hands-on physical models combined with education technology for instructors and outreach coordinators. The mission of the MEDL-CMC is to provide advanced curriculum material resources for the purpose of increasing and sustaining high impact instructional capacity in STEM education for both formal and informal learning environments. This presentation describes the development methods being used to implement the MEDL-CMC. Major development methods include: (1) adopting a project management system to support collaborations with stakeholders, (2) using a diversified funding approach to achieve financial sustainability and the ability to evolve with the educational needs of the community, and (3) establishing a broad collection of systems-based physical analog models and data collection tools to support integrated sciences such as the geosciences. Discussion will focus on how these methods are used for achieving organizational capacity in the MEDL-CMC and on their intended role in reducing instructor workload in planning both classroom activities and research grant broader impacts.

Facilitating Geoscience Education in Higher-Education Institutes Worldwide With GeoBrain -- An Online Learning and Research Environment for Classroom Innovations

NASA Astrophysics Data System (ADS)

Deng, M.; di, L.

2006-12-01

Higher education in geosciences has imminent goals to prepare students with modern geoscience knowledge and skills to meet the increased demand on trained professionals for working on the big challenges faced by geoscience disciplines, such as the global environmental change, world energy supplies, sustainable development, etc. In order to reach the goal, the geoscience education in post-secondary institutes worldwide has to attract and retain enough students and to train students with knowledge and skills needed by the society. The classroom innovations that can encourage and support student investigations and research activities are key motivation mechanisms that help to reach the goal. This presentation describes the use of GeoBrain, an innovative geospatial knowledge system, as a powerful educating tool for motivating and facilitating innovative undergraduate and graduate teaching and research in geosciences. Developed in a NASA funded project, the GeoBrain system has adopted and implemented the latest Web services and knowledge management technologies for providing innovative methods in publishing, accessing, visualizing, and analyzing geospatial data and in building/sharing geoscience knowledge. It provides a data-rich online learning and research environment enabled by wealthy data and information available at NASA Earth Observing System (EOS) Data and Information System (EOSDIS). Students, faculty members, and researchers from institutes worldwide can easily access, analyze, and model with the huge amount of NASA EOS data just like they possess such vast resources locally at their desktops. The online environment provided by GeoBrain has brought significant positive changes to geosciences education in higher-education institutes because of its new concepts and technologies, motivation mechanisms, free exploration resources, and advanced geo- processing capabilities. With the system, the used-to-be very challenging or even impossible teaching tasks has become much easier or practical. For an instance, dynamic classroom demonstration and training for students to deal with data-intensive global climate and environment change issues in real-world applications through the system has become a very pleasant experience instead of the struggling efforts in the past. With GeoBrain, each student can be easily trained to handle multi-terabytes of EOS and other geospatial data in simulation and modeling for solving global-scale problems catering his own interests with a simple Internet connected computer. Preliminary classroom use of GeoBrain in multiple universities has demonstrated that the system is very useful for facilitating the transition of both undergraduate and graduate students from learners to investigators. It has also shown the system can improve teaching effectiveness, refine student's learning habit, and inspire students' interests in pursuing geoscience as their career. As an on-going project, GeoBrain has not reached its maturity. Surely it will improve its functionalities and make great advances in the above areas continuously.

Developing A Large-Scale, Collaborative, Productive Geoscience Education Network

NASA Astrophysics Data System (ADS)

Manduca, C. A.; Bralower, T. J.; Egger, A. E.; Fox, S.; Ledley, T. S.; Macdonald, H.; Mcconnell, D. A.; Mogk, D. W.; Tewksbury, B. J.

2012-12-01

Over the past 15 years, the geoscience education community has grown substantially and developed broad and deep capacity for collaboration and dissemination of ideas. While this community is best viewed as emergent from complex interactions among changing educational needs and opportunities, we highlight the role of several large projects in the development of a network within this community. In the 1990s, three NSF projects came together to build a robust web infrastructure to support the production and dissemination of on-line resources: On The Cutting Edge (OTCE), Earth Exploration Toolbook, and Starting Point: Teaching Introductory Geoscience. Along with the contemporaneous Digital Library for Earth System Education, these projects engaged geoscience educators nationwide in exploring professional development experiences that produced lasting on-line resources, collaborative authoring of resources, and models for web-based support for geoscience teaching. As a result, a culture developed in the 2000s in which geoscience educators anticipated that resources for geoscience teaching would be shared broadly and that collaborative authoring would be productive and engaging. By this time, a diverse set of examples demonstrated the power of the web infrastructure in supporting collaboration, dissemination and professional development . Building on this foundation, more recent work has expanded both the size of the network and the scope of its work. Many large research projects initiated collaborations to disseminate resources supporting educational use of their data. Research results from the rapidly expanding geoscience education research community were integrated into the Pedagogies in Action website and OTCE. Projects engaged faculty across the nation in large-scale data collection and educational research. The Climate Literacy and Energy Awareness Network and OTCE engaged community members in reviewing the expanding body of on-line resources. Building Strong Geoscience Departments sought to create the same type of shared information base that was supporting individual faculty for departments. The Teach the Earth portal and its underlying web development tools were used by NSF-funded projects in education to disseminate their results. Leveraging these funded efforts, the Climate Literacy Network has expanded this geoscience education community to include individuals broadly interested in fostering climate literacy. Most recently, the InTeGrate project is implementing inter-institutional collaborative authoring, testing and evaluation of curricular materials. While these projects represent only a fraction of the activity in geoscience education, they are important drivers in the development of a large, national, coherent geoscience education network with the ability to collaborate and disseminate information effectively. Importantly, the community is open and defined by active participation. Key mechanisms for engagement have included alignment of project activities with participants needs and goals; productive face-to-face and virtual workshops, events, and series; stipends for completion of large products; and strong supporting staff to keep projects moving and assist with product production. One measure of its success is the adoption and adaptation of resources and models by emerging projects, which results in the continued growth of the network.

Linked data scientometrics in semantic e-Science

NASA Astrophysics Data System (ADS)

Narock, Tom; Wimmer, Hayden

2017-03-01

The Semantic Web is inherently multi-disciplinary and many domains have taken advantage of semantic technologies. Yet, the geosciences are one of the fields leading the way in Semantic Web adoption and validation. Astronomy, Earth science, hydrology, and solar-terrestrial physics have seen a noteworthy amount of semantic integration. The geoscience community has been willing early adopters of semantic technologies and have provided essential feedback to the broader semantic web community. Yet, there has been no systematic study of the community as a whole and there exists no quantitative data on the impact and status of semantic technologies in the geosciences. We explore the applicability of Linked Data to scientometrics in the geosciences. In doing so, we gain an initial understanding of the breadth and depth of the Semantic Web in the geosciences. We identify what appears to be a transitionary period in the applicability of these technologies.

EarthCube Activities: Community Engagement Advancing Geoscience Research

NASA Astrophysics Data System (ADS)

Kinkade, D.

2015-12-01

Our ability to advance scientific research in order to better understand complex Earth systems, address emerging geoscience problems, and meet societal challenges is increasingly dependent upon the concept of Open Science and Data. Although these terms are relatively new to the world of research, Open Science and Data in this context may be described as transparency in the scientific process. This includes the discoverability, public accessibility and reusability of scientific data, as well as accessibility and transparency of scientific communication (www.openscience.org). Scientists and the US government alike are realizing the critical need for easy discovery and access to multidisciplinary data to advance research in the geosciences. The NSF-supported EarthCube project was created to meet this need. EarthCube is developing a community-driven common cyberinfrastructure for the purpose of accessing, integrating, analyzing, sharing and visualizing all forms of data and related resources through advanced technological and computational capabilities. Engaging the geoscience community in EarthCube's development is crucial to its success, and EarthCube is providing several opportunities for geoscience involvement. This presentation will provide an overview of the activities EarthCube is employing to entrain the community in the development process, from governance development and strategic planning, to technical needs gathering. Particular focus will be given to the collection of science-driven use cases as a means of capturing scientific and technical requirements. Such activities inform the development of key technical and computational components that collectively will form a cyberinfrastructure to meet the research needs of the geoscience community.

Contracts for field projects and supporting research on enhanced oil recovery. Progress review number 83, quarter ending June 30, 1995

DOE Office of Scientific and Technical Information (OSTI.GOV)

NONE

Summaries of 41 research projects on enhanced recovery are presented under the following sections: (1) chemical flooding; (2) gas displacement; (3) thermal recovery; (4) geoscience technology; (5) resource assessment technology; and (6) reservoir classes. Each presentation gives the title of the project, contract number, research facility, contract date, expected completion data, amount of the award, principal investigator, and DOE program manager, and describes the objectives of the project and a summary of the technical progress.

Information needs and behaviors of geoscience educators: A grounded theory study

NASA Astrophysics Data System (ADS)

Aber, Susan Ward

2005-12-01

Geoscience educators use a variety of resources and resource formats in their classroom teaching to facilitate student understanding of concepts and processes that define subject areas considered in the realm of geoscience. In this study of information needs and behaviors of geoscience educators, the researcher found that participants preferred visual media such as personal photographic and digital images, as well as published figures, animations, and cartoons, and that participants bypassed their academic libraries to meet these information needs. In order to investigate the role of information in developing introductory geoscience course and instruction, a grounded theory study was conducted through a qualitative paradigm with an interpretive approach and naturalistic inquiry. The theoretical and methodological framework was constructivism and sense-making. Research questions were posited on the nature of geoscience subject areas and the resources and resource formats used in conveying geoscience topics to science and non-science majors, as well as educators' preferences and concerns with curriculum and instruction. The underlying framework was to investigate the place of the academic library and librarian in the sense-making, constructivist approach of geoscience educators. A purposive sample of seven geoscience educators from four universities located in mid-western United States was identified as exemplary teachers by department chairpersons. A triangulation of data collection methods included semi-structured interviews, document reviews, and classroom observations. Data were analyzed using the constant comparative method, which included coding, categorizing, and interpreting for patterns and relationships. Contextual factors were identified and a simple model resulted showing the role of information in teaching for these participants. While participants developed lectures and demonstrations using intrapersonal knowledge and personal collections, one barrier was a lack of time and funding for converting photographic prints and slides to digital images. Findings have implications for academic librarians to provide more visual media or assistance with organizing and formatting existing outdated media formats and to create collaborative collection development through repackaging personal collections of geoscience participants to enhance teaching. Implications for library school educators include providing curriculum on information needs and behaviors from a user's perspective, subject specialty librarianship, and internal collaborative collection development to complement external collection development.

Evaluating open-source cloud computing solutions for geosciences

NASA Astrophysics Data System (ADS)

Huang, Qunying; Yang, Chaowei; Liu, Kai; Xia, Jizhe; Xu, Chen; Li, Jing; Gui, Zhipeng; Sun, Min; Li, Zhenglong

2013-09-01

Many organizations start to adopt cloud computing for better utilizing computing resources by taking advantage of its scalability, cost reduction, and easy to access characteristics. Many private or community cloud computing platforms are being built using open-source cloud solutions. However, little has been done to systematically compare and evaluate the features and performance of open-source solutions in supporting Geosciences. This paper provides a comprehensive study of three open-source cloud solutions, including OpenNebula, Eucalyptus, and CloudStack. We compared a variety of features, capabilities, technologies and performances including: (1) general features and supported services for cloud resource creation and management, (2) advanced capabilities for networking and security, and (3) the performance of the cloud solutions in provisioning and operating the cloud resources as well as the performance of virtual machines initiated and managed by the cloud solutions in supporting selected geoscience applications. Our study found that: (1) no significant performance differences in central processing unit (CPU), memory and I/O of virtual machines created and managed by different solutions, (2) OpenNebula has the fastest internal network while both Eucalyptus and CloudStack have better virtual machine isolation and security strategies, (3) Cloudstack has the fastest operations in handling virtual machines, images, snapshots, volumes and networking, followed by OpenNebula, and (4) the selected cloud computing solutions are capable for supporting concurrent intensive web applications, computing intensive applications, and small-scale model simulations without intensive data communication.

EarthCube Cyberinfrastructure: The Importance of and Need for International Strategic Partnerships to Enhance Interconnectivity and Interoperability

NASA Astrophysics Data System (ADS)

Ramamurthy, M. K.; Lehnert, K.; Zanzerkia, E. E.

2017-12-01

The United States National Science Foundation's EarthCube program is a community-driven activity aimed at transforming the conduct of geosciences research and education by creating a well-connected cyberinfrastructure for sharing and integrating data and knowledge across all geoscience disciplines in an open, transparent, and inclusive manner and to accelerate our ability to understand and predict the Earth system. After five years of community engagement, governance, and development activities, EarthCube is now transitioning into an implementation phase. In the first phase of implementing the EarthCube architecture, the project leadership has identified the following architectural components as the top three priorities, focused on technologies, interfaces and interoperability elements that will address: a) Resource Discovery; b) Resource Registry; and c) Resource Distribution and Access. Simultaneously, EarthCube is exploring international partnerships to leverage synergies with other e-infrastructure programs and projects in Europe, Australia, and other regions and discuss potential partnerships and mutually beneficial collaborations to increase interoperability of systems for advancing EarthCube's goals in an efficient and effective manner. In this session, we will present the progress of EarthCube on a number of fronts and engage geoscientists and data scientists in the future steps toward the development of EarthCube for advancing research and discovery in the geosciences. The talk will underscore the importance of strategic partnerships with other like eScience projects and programs across the globe.

Mathematics Prerequisites for Introductory Geoscience Courses: Using Technology to Help Solve the Problem

NASA Astrophysics Data System (ADS)

Burn, H. E.; Wenner, J. M.; Baer, E. M.

2011-12-01

The quantitative components of introductory geoscience courses can pose significant barriers to students. Many academic departments respond by stripping courses of their quantitative components or by attaching prerequisite mathematics courses [PMC]. PMCs cause students to incur additional costs and credits and may deter enrollment in introductory courses; yet, stripping quantitative content from geoscience courses masks the data-rich, quantitative nature of geoscience. Furthermore, the diversity of math skills required in geoscience and students' difficulty with transferring mathematical knowledge across domains suggest that PMCs may be ineffective. Instead, this study explores an alternative strategy -- to remediate students' mathematical skills using online modules that provide students with opportunities to build contextual quantitative reasoning skills. The Math You Need, When You Need It [TMYN] is a set of modular online student resources that address mathematical concepts in the context of the geosciences. TMYN modules are online resources that employ a "just-in-time" approach - giving students access to skills and then immediately providing opportunities to apply them. Each module places the mathematical concept in multiple geoscience contexts. Such an approach illustrates the immediate application of a principle and provides repeated exposure to a mathematical skill, enhancing long-term retention. At the same time, placing mathematics directly in several geoscience contexts better promotes transfer of learning by using similar discourse (words, tools, representations) and context that students will encounter when applying mathematics in the future. This study uses quantitative and qualitative data to explore the effectiveness of TMYN modules in remediating students' mathematical skills. Quantitative data derive from ten geoscience courses that used TMYN modules during the fall 2010 and spring 2011 semesters; none of the courses had a PMC. In all courses, students completed a pretest, the assigned modules, and a posttest. Success in remediation was measured using normalized gain scores, which measures the change in score divided by the maximum possible increase: (posttest-pretest)/(1-pretest). To compare across courses, normalized gain scores were standardized. Additional analysis included disaggregating normalized gain scores by quartiles based on pretest scores. The results were supplemented by qualitative data from faculty interviews and information provided by faculty on a web form upon completion of the course. Results suggest TMYN modules remediate mathematical skills effectively, and that normalized gains tend to be higher for students in the lower quartiles on the pretest. Students indicate finding the modules helpful, though sometimes difficult. Faculty interview data triangulate these findings and provide further evidence that online, modularized remediation is an effective alternative to assigning prerequisite mathematical courses to remediate mathematical skills.

Geo-Needs: Investigating Models for Improved Access to Geosciences at Two-Year and Minority-Serving Colleges

NASA Astrophysics Data System (ADS)

Her, X.; Turner, S. P.; LaDue, N.; Bentley, A. P.; Petcovic, H. L.; Mogk, D. W.; Cartwright, T.

2015-12-01

Geosciences are an important field of study for the future of energy, water, climate resilience, and infrastructure in our country. Geoscience related job growth is expected to steeply climb in the United States, however many of these positions will be left unfilled. One untapped population of Americans is ethnic minorities, who have historically been underrepresented in the geosciences. In 2010, the Bureau of Labor Statistics (BLS) reported that black and Hispanics only make 8.1% of geoscience related jobs, while making up nearly 30% of Americans. This pattern of underrepresentation has been attributed to 1) minority serving institutions lacking geoscience programs, 2) low interest in the outdoors due to a lack of opportunity, and 3) negative and low prestigious perceptions of geoscientists. Our project focuses specifically on the first barrier. Preliminary research suggests that only 2.5% of institutions with geoscience programs (n= 609) are also minority serving. The goals of the Geo-Needs project are to identify obstacles to and opportunities for better use of existing educational resources in two-year and minority-serving institutions, and to explore "ideal" models of resources, partnerships, and other support for geoscience faculty and students in these institutions. Four focus group meetings were held in August 2015 bringing administrators, instructors, resource providers, and education researchers together to discuss and develop these models. Activities at the meetings included small and whole group prompted discussion, guest speakers, gallery walks, and individual reflection. Content from the focus group meetings is available at the project's website: http://serc.carleton.edu/geoneeds/index.html. Findings from the meetings can be used to inform future efforts aimed toward broadening access to the geosciences at two-year and minority-serving institutions.

Effectiveness of Geosciences Exploration Summer Program (GeoX) for Increasing Awareness and Knowledge of Geosciences

ERIC Educational Resources Information Center

Houser, Chris; Garcia, Sonia; Torres, Janet

2015-01-01

Summer research experiences are an increasingly popular means of increasing awareness of, and developing interest in, the geosciences and other science, technology, engineering, and math programs. We describe and report the preliminary results of a 1-wk Geosciences Exploration Summer Program in the College of Geosciences at Texas A&M…

The First Hydrology (Geoscience) Degree at a Tribal College or University: Salish Kootenai College

NASA Astrophysics Data System (ADS)

Lesser, G.; Berthelote, A. R.

2010-12-01

A new Hydrology Degree Program was developed at Salish and Kootenai College in western Montana. This program will begin to address the fact that our nation only awards 20 to 30 Geoscience degrees annually to Native American students. Previously absent from SKC and the other 36 Tribal Colleges or Universities (TCU) Science, Technology, Engineering, and Mathematics (STEM) related programs are specific Geoscience disciplines, particularly those focusing on hydrological and water based sciences. Though 23 TCU’s offer some classes to supplement their environmental science or natural resource programs. This program is timely and essential for addressing the concerns that Native Americans have who maintain sovereignty over approximately 20% of our nation’s fresh water resources which are becoming more stressed each year. The overall objective of this new SKC Hydrology degree program is to produce students who are able to “give voice” to the perspectives of Native peoples on natural resources and particularly water-related issues, including water rights, agriculture, environmental health (related to water), beliefs and spirituality related to water, and sustainability of water resources. It will provide the opportunity for interdisciplinary study in physical, chemical, and biological water resources and their management. Students will gain theoretical, conceptual, computational, and practical knowledge/experiences in quantifying, monitoring, qualifying, and managing today’s water resource challenges with particular emphasis on Tribal lands. Completion of the Associate of Science Degree will provide the student with the necessary skills to work as a hydrology- water quality- or geo-technician within the Reservation area, the U. S. Forest Service, the Environmental Protection Agency, the Bureau of Reclamation, the United States Geological Society, and other earth science disciplines. The Bachelor’s Degree program provides students with a broad-based theoretical and technological understanding of environmental and physical sciences and prepares students to design and direct research and programs related to water resources. Graduates of the Bachelor of Science Degree program are prepared to continue their education in graduate school or obtain employment as managers or directors of programs in industry, consulting, local, state, federal and tribal programs. Graduates will find that due to sovereignty issues, most tribes either have in place or are seeking trained professionals to monitor, manage, and protect their respective water resources. Hydrology and Geoscience job openings are expected to continue to exceed the number of qualified jobseekers through the 2018 projection period. And, nationally, 1 in 4 geoscientist positions are employed as hydrologists (30% engineering related services, 30 % Government, and 20% management and technical consulting). The mission of SKC is to provide quality postsecondary educational opportunities for Native Americans, locally and from throughout the United States, and defines cultural understanding as: "The awareness of your own system of values, beliefs, traditions and history, and knowledge and respect for the systems of others, particularly those of American Indian Tribes, and specifically the Salish, Pend d'Oreille and Kootenai People".

Native Geosciences: Strengthening the Future Through Tribal Traditions

NASA Astrophysics Data System (ADS)

Bolman, J. R.; Quigley, I.; Douville, V.; Hollow Horn Bear, D.

2008-12-01

Native people have lived for millennia in distinct and unique ways in our natural sacred homelands and environments. Tribal cultures are the expression of deep understandings of geosciences shared through oral histories, language and ceremonies. Today, Native people as all people are living in a definite time of change. The developing awareness of "change" brings forth an immense opportunity to expand and elevate Native geosciences knowledge, specifically in the areas of earth, wind, fire and water. At the center of "change" is the need to balance the needs of the people with the needs of the environment. Native tradition and our inherent understanding of what is "sacred above is sacred below" is the foundation for an emerging multi-faceted approach to increasing the representation of Natives in geosciences. The approach is also a pathway to assist in Tribal language revitalization, connection of oral histories and ceremonies as well as building an intergenerational teaching/learning community. Humboldt State University, Sinte Gleska University and South Dakota School of Mines and Technology in partnership with Northern California (Hoopa, Yurok, & Karuk) and Great Plains (Lakota) Tribes have nurtured Native geosciences learning communities connected to Tribal Sacred Sites and natural resources. These sites include the Black Hills (Mato Paha, Mato Tiplia, Hinhan Kaga Paha, Mako Sica etc.), Klamath River (Ishkêesh), and Hoopa Valley (Natinixwe). Native geosciences learning is centered on the themes of earth, wind, fire and water and Native application of remote sensing technologies. Tribal Elders and Native geoscientists work collaboratively providing Native families in-field experiential intergenerational learning opportunities which invite participants to immerse themselves spiritually, intellectually, physically and emotionally in the experiences. Through this immersion and experience Native students and families strengthen the circle of our future Tribal communities and a return to traditional ways of supporting the development of our "story" or purpose for being. The opportunities include residential summer field experiences, interdisciplinary curriculums and development of Tribally-driven Native research experiences. The National Science Foundation, University of North Dakota's Northern Great Plains Center for People and the Environment, Upper Midwest Aerospace Consortium (UMAC), and Tribes have provided funding to support the development of Native geosciences. The presentation will focus on current projects: NSF OEDG "He Sapa Bloketu Woecun; Geosciences at the Heart of Everything That Is", NSF S-STEM "Scientific Leadership Scholars" and the NSF BPC "Coalition of American Indians in Computing". The expressed goal of future initiatives is to connect Tribal communities across the Midwest and West in developing a Native Geosciences Pathway. This pathway supports the identification and support of Tribal students with an interest or "story" connected to geosciences ensuring a future Native geosciences workforce.

Architecture for the Interdisciplinary Earth Data Alliance

NASA Astrophysics Data System (ADS)

Richard, S. M.

2016-12-01

The Interdisciplinary Earth Data Alliance (IEDA) is leading an EarthCube (EC) Integrative Activity to develop a governance structure and technology framework that enables partner data systems to share technology, infrastructure, and practice for documenting, curating, and accessing heterogeneous geoscience data. The IEDA data facility provides capabilities in an extensible framework that enables domain-specific requirements for each partner system in the Alliance to be integrated into standardized cross-domain workflows. The shared technology infrastructure includes a data submission hub, a domain-agnostic file-based repository, an integrated Alliance catalog and a Data Browser for data discovery across all partner holdings, as well as services for registering identifiers for datasets (DOI) and samples (IGSN). The submission hub will be a platform that facilitates acquisition of cross-domain resource documentation and channels users into domain and resource-specific workflows tailored for each partner community. We are exploring an event-based message bus architecture with a standardized plug-in interface for adding capabilities. This architecture builds on the EC CINERGI metadata pipeline as well as the message-based architecture of the SEAD project. Plug-in components for file introspection to match entities to a data type registry (extending EC Digital Crust and Research Data Alliance work), extract standardized keywords (using CINERGI components), location, cruise, personnel and other metadata linkage information (building on GeoLink and existing IEDA partner components). The submission hub will feed submissions to appropriate partner repositories and service endpoints targeted by domain and resource type for distribution. The Alliance governance will adopt patterns (vocabularies, operations, resource types) for self-describing data services using standard HTTP protocol for simplified data access (building on EC GeoWS and other `RESTful' approaches). Exposure of resource descriptions (datasets and service distributions) for harvesting by commercial search engines as well as geoscience-data focused crawlers (like EC B-Cube crawler) will increase discoverability of IEDA resources with minimal effort by curators.

A Compilation and Review of over 500 Geoscience Misconceptions

ERIC Educational Resources Information Center

Francek, Mark

2013-01-01

This paper organizes and analyses over 500 geoscience misconceptions relating to earthquakes, earth structure, geologic resources, glaciers, historical geology, karst (limestone terrains), plate tectonics, rivers, rocks and minerals, soils, volcanoes, and weathering and erosion. Journal and reliable web resources were reviewed to discover (1) the…

The DLESE Evaluation Toolkit Project

NASA Astrophysics Data System (ADS)

Buhr, S. M.; Barker, L. J.; Marlino, M.

2002-12-01

The Evaluation Toolkit and Community project is a new Digital Library for Earth System Education (DLESE) collection designed to raise awareness of project evaluation within the geoscience education community, and to enable principal investigators, teachers, and evaluators to implement project evaluation more readily. This new resource is grounded in the needs of geoscience educators, and will provide a virtual home for a geoscience education evaluation community. The goals of the project are to 1) provide a robust collection of evaluation resources useful for Earth systems educators, 2) establish a forum and community for evaluation dialogue within DLESE, and 3) disseminate the resources through the DLESE infrastructure and through professional society workshops and proceedings. Collaboration and expertise in education, geoscience and evaluation are necessary if we are to conduct the best possible geoscience education. The Toolkit allows users to engage in evaluation at whichever level best suits their needs, get more evaluation professional development if desired, and access the expertise of other segments of the community. To date, a test web site has been built and populated, initial community feedback from the DLESE and broader community is being garnered, and we have begun to heighten awareness of geoscience education evaluation within our community. The web site contains features that allow users to access professional development about evaluation, search and find evaluation resources, submit resources, find or offer evaluation services, sign up for upcoming workshops, take the user survey, and submit calendar items. The evaluation resource matrix currently contains resources that have met our initial review. The resources are currently organized by type; they will become searchable on multiple dimensions of project type, audience, objectives and evaluation resource type as efforts to develop a collection-specific search engine mature. The peer review criteria and process for ensuring that the site contains robust and useful resources has been drafted and received initial feedback from the project advisory board, which consists of members of every segment of the target audience. The review criteria are based upon DLESE peer review criteria, the MERLOT digital library peer review criteria, digital resource evaluation criteria, and evaluation best practices. In geoscience education, as in most endeavors, improvements are made by asking questions and acting upon information about successes and failures; project evaluation can be thought of as the systematic process of asking these questions and gathering the right information. The Evaluation Toolkit seeks to help principal investigators, teachers, and evaluators use the evaluation process to improve our projects and our field.

Developing Geosciences Research Partnerships With Colleagues from SOPAC

NASA Astrophysics Data System (ADS)

Edsall, D. W.

2003-12-01

Members of the AGU have an opportunity to become involved in cooperative research with scientists from the Cook Islands, Fiji, Guam, Federated States of Micronesia, Kiribati, Marshall Islands, Papua New Guinea, Solomon Islands, Tonga, Tuvalu, Vanuatu, Western Samoa as well as Australia and New Zealand. Governmental officials and scientists from the member countries of the South Pacific Applied Geoscience Commission (SOPAC) and its Science Technology and Resources Network (STAR) are looking for individuals, academic and research organizations, foundations, private industry, governmental agencies and professional societies to assist with important research efforts. Involvement would include: promoting; training; funding; equipping, facilitating; coordinating; advising; monitoring; collaborating; interpreting; evaluating and reporting. Studies in all onshore, coastal and offshore environments are needed. Topics include: development of natural resources; reduction of environmental vulnerability; support of sustainable development; development of potable water supplies; protecting coral reef environments; and basic investigations of local weather, climatology, biology, geology, geophysics and oceanography. This paper addresses ways to create such research partnerships.

Building Strong Geoscience Departments: Resources and Opportunities

NASA Astrophysics Data System (ADS)

Manduca, C. A.; MacDonald, R. H.; Feiss, P. G.; Richardson, R. M.; Ormand, C. J.

2008-12-01

The Building Strong Geoscience Departments program aims to foster communication and sharing among geoscience departments in order to allow for rapid dissemination of strong ideas and approaches. Sponsored by NAGT, AGI, AGU, and GSA, the project has developed a rich set of web resources, offered workshops on topics from recruiting students to developing a curriculum for the future, and hosted on-line discussion of high interest topics including accreditation. Online resources (http://serc.carleton.edu/departments/index.html) feature successful strategies and specific examples from a wide variety of geoscience departments across North America. These resources address student recruitment, development and assessment of curricula and programs, preparing students for careers, and the future of geoscience. This year the program will offer two new workshops (http://serc.carleton.edu/departments/workshops/index.html). The first, in February, will focus on assessing geoscience programs. Departments are increasingly called upon to assess the impact of their programs on students and to measure the degree to which they meet stated goals. This workshop will showcase the methods and instruments that geoscience departments are using for this assessment, as well as providing opportunities to learn more about evaluation theory and practice from experts in the field. The second workshop, in June, is designed to help departmental teams develop practical solutions to the challenges they currently face. Building on past workshops in this series, participants will help shape the focus of the workshop to meet their needs in areas such as curriculum, assessment, programming, recruitment, or management. A goal of this workshop is to put into broader use the wealth of examples and ideas documented on the project website.

Preparing Future Geoscience Professionals: Needs, Strategies, Programs, and Online Resources

NASA Astrophysics Data System (ADS)

Macdonald, H.; Manduca, C. A.; Ormand, C. J.; Dunbar, R. W.; Beane, R. J.; Bruckner, M.; Bralower, T. J.; Feiss, P. G.; Tewksbury, B. J.; Wiese, K.

2011-12-01

Geoscience faculty, departments, and programs play an important role in preparing future geoscience professionals. One challenge is supporting the diversity of student goals for future employment and the needs of a wide range of potential employers. Students in geoscience degree programs pursue careers in traditional geoscience industries; in geoscience education and research (including K-12 teaching); and opportunities at the intersection of geoscience and other fields (e.g., policy, law, business). The Building Strong Geoscience Departments project has documented a range of approaches that departments use to support the development of geoscience majors as professionals (serc.carleton.edu/departments). On the Cutting Edge, a professional development program, supports graduate students and post-doctoral fellows interested in pursuing an academic career through workshops, webinars, and online resources (serc.carleton.edu/NAGTWorkshops/careerprep). Geoscience departments work at the intersection of student interests and employer needs. Commonly cited program goals that align with employer needs include mastery of geoscience content; field experience; skill in problem solving, quantitative reasoning, communication, and collaboration; and the ability to learn independently and take a project from start to finish. Departments and faculty can address workforce issues by 1) implementing of degree programs that develop the knowledge, skills, and attitudes that students need, while recognizing that students have a diversity of career goals; 2) introducing career options to majors and potential majors and encouraging exploration of options; 3) advising students on how to prepare for specific career paths; 4) helping students develop into professionals, and 5) supporting students in the job search. It is valuable to build connections with geoscience employers, work with alumni and foster connections between students and alumni with similar career interests, collaborate with campus career centers, incorporate career advising and mentoring throughout the degree program, and recognize that co-curricular experiences are also important avenues through which students can also develop as professionals. Graduate students and post-doctoral fellows have many questions about academic jobs and the academic job search process and many are uncertain about the nature of academic positions at different kinds of educational institutions (two-year colleges, primarily undergraduate institutions, and research universities). On the Cutting Edge workshops and webinars provide insights into academic careers in different institutional settings, various teaching strategies and course design, strategies for moving research forward, effective teaching and research statements, the job search process, and negotiation. The website provides resources on these topics as well as others and includes screen casts of the webinar sessions, making these resources available to all.

Making the Case for GeoSTEM Education

NASA Astrophysics Data System (ADS)

Moore, John

2014-05-01

As the national Science-Technology-Engineering-Mathematics (STEM) education policy makers in the United States work through reports, findings, forums, workshops, etc., there emerges an opportunity to present the strong case of why and how the role of the Geosciences community can and should be at the forefront of these discussions. Currently existing within the Geosciences scientific and educational community are policies, frameworks, guidance, innovative technology, and unique interdisciplinary Earth System data sets that will establish a pathway to the role of the Geosciences in the classroom, in the 21st Century workforce, and in society. The question may be raised, "Why GeoSTEM?" But the real question should be … "Why not?" Over the past several years the Geosciences have dominated the news cycle in the United States. As we face future natural and human generated hazards and disasters such as the Gulf Oil Spill, not to mention issues confronting society such as Climate Change, Sustainability and Energy, the Geosciences have a critical role in the public awareness, safety, and national security of our nation. In the past year we have experienced volcanic eruptions, earth¬quakes, tsunamis, hurricanes, tornadoes, wildfires, severe drought and flooding, outbreaks of severe weather. Planet Earth will be monitored, observed, and studied as an Earth System, in real or near real time. Policy-makers, decision-makers, scientists, teachers, students, and citizens will not only participate in the process, but come to use such information and data routinely in their daily lives. 3-D data visualizations, virtual field trips, and interactive imagery from space all will contribute to the doing of real science in real time. Policy-Makers have linked Science, Technology, Engineering, and Mathematics (STEM) Education to United States' future economy and national security. The GeoSTEM community can deliver added value through leveraging current and future Geoscience-related resources that monitor our planet and protect the life and property of our citizens. The integration of a Geoscience and Remote Sensing Laboratory into an existing Earth Science program or a new Earth Systems Science course allows students to acquire the necessary rigorous laboratory skills as required by colleges or universities, while developing and becoming proficient in technological skills using industry standard analysis tools. With the accessibility of real-time or near real time data, students in a GeoSTEM driven course can engage in inquiry-based laboratory experiences focusing on real life applications, both local and global. Developing pathways between geoscientists, researchers, teachers, and students, will create an exchange of information, data, observations, and measurements that will lead to authentic science investigations through the monitoring of weather, water quality, sea surface temperature, coral reefs, marine wildlife, earthquakes, tsunamis, wildfires, air quality, land cover, and much more. Satellite, remote sensing, and geospatial technologies can introduce students and society to data that can inform policy makers and society both now and in the future.

Developing a Science Commons for Geosciences

NASA Astrophysics Data System (ADS)

Lenhardt, W. C.; Lander, H.

2016-12-01

Many scientific communities, recognizing the research possibilities inherent in data sets, have created domain specific archives such as the Incorporated Research Institutions for Seismology (iris.edu) and ClinicalTrials.gov. Though this is an important step forward, most scientists, including geoscientists, also use a variety of software tools and at least some amount of computation to conduct their research. While the archives make it simpler for scientists to locate the required data, provisioning disk space, compute resources, and network bandwidth can still require significant efforts. This challenge exists despite the wealth of resources available to researchers, namely lab IT resources, institutional IT resources, national compute resources (XSEDE, OSG), private clouds, public clouds, and the development of cyberinfrastructure technologies meant to facilitate use of those resources. Further tasks include obtaining and installing required tools for analysis and visualization. If the research effort is a collaboration or involves certain types of data, then the partners may well have additional non-scientific tasks such as securing the data and developing secure sharing methods for the data. These requirements motivate our investigations into the "Science Commons". This paper will present a working definition of a science commons, compare and contrast examples of existing science commons, and describe a project based at RENCI to implement a science commons for risk analytics. We will then explore what a similar tool might look like for the geosciences.

Integrating Semantic Information in Metadata Descriptions for a Geoscience-wide Resource Inventory.

NASA Astrophysics Data System (ADS)

Zaslavsky, I.; Richard, S. M.; Gupta, A.; Valentine, D.; Whitenack, T.; Ozyurt, I. B.; Grethe, J. S.; Schachne, A.

2016-12-01

Integrating semantic information into legacy metadata catalogs is a challenging issue and so far has been mostly done on a limited scale. We present experience of CINERGI (Community Inventory of Earthcube Resources for Geoscience Interoperability), an NSF Earthcube Building Block project, in creating a large cross-disciplinary catalog of geoscience information resources to enable cross-domain discovery. The project developed a pipeline for automatically augmenting resource metadata, in particular generating keywords that describe metadata documents harvested from multiple geoscience information repositories or contributed by geoscientists through various channels including surveys and domain resource inventories. The pipeline examines available metadata descriptions using text parsing, vocabulary management and semantic annotation and graph navigation services of GeoSciGraph. GeoSciGraph, in turn, relies on a large cross-domain ontology of geoscience terms, which bridges several independently developed ontologies or taxonomies including SWEET, ENVO, YAGO, GeoSciML, GCMD, SWO, and CHEBI. The ontology content enables automatic extraction of keywords reflecting science domains, equipment used, geospatial features, measured properties, methods, processes, etc. We specifically focus on issues of cross-domain geoscience ontology creation, resolving several types of semantic conflicts among component ontologies or vocabularies, and constructing and managing facets for improved data discovery and navigation. The ontology and keyword generation rules are iteratively improved as pipeline results are presented to data managers for selective manual curation via a CINERGI Annotator user interface. We present lessons learned from applying CINERGI metadata augmentation pipeline to a number of federal agency and academic data registries, in the context of several use cases that require data discovery and integration across multiple earth science data catalogs of varying quality and completeness. The inventory is accessible at http://cinergi.sdsc.edu, and the CINERGI project web page is http://earthcube.org/group/cinergi

Developing Resources for Teaching Ethics in Geoscience

NASA Astrophysics Data System (ADS)

Mogk, David W.; Geissman, John W.

2014-11-01

Ethics education is an increasingly important component of the pre-professional training of geoscientists. Geoethics encompasses the values and professional standards required of geoscientists to work responsibly in any geoscience profession and in service to society. Funding agencies (e.g., the National Science Foundation, the National Institutes of Health) require training of graduate students in the responsible conduct of research; employers are increasingly expecting their workers to have basic training in ethics; and the public demands the highest standards of ethical conduct by scientists. However, there is currently no formal course of instruction in ethics in the geoscience curriculum, and few faculty members have the experience, resources, and sometimes willingness required to teach ethics as a component of their geoscience courses.

Turning Interoperability Operational with GST

NASA Astrophysics Data System (ADS)

Schaeben, Helmut; Gabriel, Paul; Gietzel, Jan; Le, Hai Ha

2013-04-01

GST - Geosciences in space and time is being developed and implemented as hub to facilitate the exchange of spatially and temporally indexed multi-dimensional geoscience data and corresponding geomodels amongst partners. It originates from TUBAF's contribution to the EU project "ProMine" and its perspective extensions are TUBAF's contribution to the actual EU project "GeoMol". As of today, it provides basic components of a geodata infrastructure as required to establish interoperability with respect to geosciences. Generally, interoperability means the facilitation of cross-border and cross-sector information exchange, taking into account legal, organisational, semantic and technical aspects, cf. Interoperability Solutions for European Public Administrations (ISA), cf. http://ec.europa.eu/isa/. Practical interoperability for partners of a joint geoscience project, say European Geological Surveys acting in a border region, means in particular provision of IT technology to exchange spatially and maybe additionally temporally indexed multi-dimensional geoscience data and corresponding models, i.e. the objects composing geomodels capturing the geometry, topology, and various geoscience contents. Geodata Infrastructure (GDI) and interoperability are objectives of several inititatives, e.g. INSPIRE, OneGeology-Europe, and most recently EGDI-SCOPE to name just the most prominent ones. Then there are quite a few markup languages (ML) related to geographical or geological information like GeoSciML, EarthResourceML, BoreholeML, ResqML for reservoir characterization, earth and reservoir models, and many others featuring geoscience information. Several Web Services are focused on geographical or geoscience information. The Open Geospatial Consortium (OGC) promotes specifications of a Web Feature Service (WFS), a Web Map Service (WMS), a Web Coverage Serverice (WCS), a Web 3D Service (W3DS), and many more. It will be clarified how GST is related to these initiatives, especially how it complies with existing or developing standards or quasi-standards and how it applies and extents services towards interoperability in the Earth sciences.

An Effective Model for Enhancing Underrepresented Minority Participation and Success in Geoscience Undergraduate Research

ERIC Educational Resources Information Center

Blake, Reginald A.; Liou-Mark, Janet; Chukuigwe, Chinedu

2013-01-01

Geoscience research is a fundamental portal through which geoscience knowledge may be acquired and disseminated. A viable model to introduce, stimulate, and prolong geoscience education has been designed and implemented at the New York City College of Technology through a National Science Foundation (NSF) Research Experiences for Undergraduates…

Cultivating Research Skills: An interdisciplinary approach in training and supporting energy research

NASA Astrophysics Data System (ADS)

Winkler, H.; Carbajales-Dale, P.; Alschbach, E.

2013-12-01

Geoscience and energy research has essentially separate and diverse tracks and traditions, making the education process labor-intensive and burdensome. Using a combined forces approach to training, a multidisciplinary workshop on information and data sources and research skills was developed and offered through several departments at Stanford University. The popular workshops taught required skills to scientists - giving training on new technologies, access to restricted energy-related scientific and government databases, search strategies for data-driven resources, and visualization and geospatial analytics. Feedback and data suggest these workshops were fundamental as they set the foundation for subsequent learning opportunities for students and faculty. This session looks at the integration of the information workshops within multiple energy and geoscience programs and the importance of formally cultivating research and information skills.

Ethnic differences in geoscience attitudes of college students

NASA Astrophysics Data System (ADS)

Whitney, David J.; Behl, Richard J.; Ambos, Elizabeth L.; Francis, R. Daniel; Holk, Gregory; Larson, Daniel O.; Lee, Christopher T.; Rodrique, Christine M.; Wechsler, Suzanne P.

While a gender balance remains elusive in the geosciences [de Wet et al., 2002], the underrepresentation of ethnic minorities in these fields is at least as great a concern.A number of cultural and social factors have been proposed to explain the poor ethnic minority representation in the geosciences, including limited exposure to nature, deficient academic preparation, inadequate financial resources to pursue higher education, ignorance of career opportunities in the geosciences, insufficient family support, and misconceptions of the field.

Website Resources and Support for Two-Year College Geoscience Educators

NASA Astrophysics Data System (ADS)

McDaris, J. R.; Macdonald, H.; Blodgett, R. H.; Manduca, C. A.; Maier, M.

2011-12-01

Geoscience faculty at two-year colleges (2YC) face a number of challenges, from the wide diversity of the student population to being isolated from other geoscience faculty. Several projects have developed web resources that address some of these issues by providing professional development, teaching materials, and opportunities to connect with their colleagues at other institutions. The Role of Two-Year Colleges in Geoscience Education and in Broadening Participation in the Geosciences project brought together 2YC faculty from across the country for a planning workshop to discuss these issues and propose strategies and mechanisms to strengthen the 2YC geoscience education community (http://serc.carleton.edu/geo2yc/index.html). The website now hosts more than 30 essays on the state of 2YC education, teaching activities, and course descriptions submitted by 2YC faculty as well as an email discussion list and other ways of networking and discussing important. One outcome of this work is that the National Association of Geoscience Teachers has created a division for 2YC faculty so that members can network with each other and discuss solutions to pressing issues. (http://nagt.org/nagt/divisions/2yc/index.html) The On the Cutting Edge program has an array of professional development resources available (http://serc.carleton.edu/NAGTWorkshops/). Over its decade of work, the program has developed resources on topics of interest to 2YC faculty including: teaching introductory courses, the affective domain, teaching with data, metacognition, online courses, teaching about hazards, and many others. There are also extensive collections of teaching activities and visualizations. In addition, the program continues to hold face-to-face and virtual professional development workshops and webinars that are accessible to 2YC faculty and can help them feel less isolated The Starting Point: Teaching Introductory Geoscience (http://serc.carleton.edu/introgeo) website is specifically aimed at all those teaching introductory classes, including two-year college faculty. This website includes information about a variety of teaching strategies (e.g., lecture tutorials, service learning, just-in-time teaching) and a set of geoscience teaching examples. This is valuable for faculty interested in new approaches to teaching or who want to see examples of activities they can adopt or adapt. The interdisciplinary project Two-year College Outreach Across the Disciplines (http://serc.carleton.edu/econ/2yc/disciplines/index.html) summarizes best practices in nine disciplines, including the geosciences. At a 2011 workshop, sponsored by Economics at Community Colleges, faculty compared notes on what has worked and what hasn't in terms of strengthening disciplinary and interdisciplinary education at 2YCs. (http://serc.carleton.edu/econ/2yc/index.html) These and other projects have developed resources for supporting and enhancing the efforts of two-year college faculty in the geosciences. A variety of these materials is available via the Teach the Earth portal at http://serc.carleton.edu/teachearth/.

Making the GeoConnection: Web 2.0-based support for early-career geoscientists (Invited)

NASA Astrophysics Data System (ADS)

Martinez, C. M.; Gonzales, L. M.; Keane, C. M.

2010-12-01

The US Bureau of Labor estimates that there will be an 18% increase in geoscience jobs between 2008 and 2018 in the United States, and demand for geoscientists is expected to rise worldwide as scientists tackle global challenges related to resources, hazards and climate. At the same time, the geoscience workforce is aging, with approximately half of the current workforce reaching retirement age within the next 10-15 years. A new generation of geoscientists must be ready to take the reins. To support this new generation, AGI’s geoscience workforce outreach programs were designed to help retain geoscience students through their degree programs and into careers in the field. These resources include support for early-career professional development and career planning. AGI’s GeoConnection Network for the Geosciences provides a venue for informal dissemination of career information and professional resources. The network links Web 2.0 platforms, including a Facebook page, YouTube Channel and Twitter feed, to build a robust geoscience community of geoscientists at all stages of their careers. Early-career geoscientists can participate in GeoConnection to network with other scientists, and to receive information about professional development and job opportunities. Through GeoConnection packets, students can join professional societies which will assist their transition from school to the workplace. AGI’s member societies provide professional development course work, field trips, career services, interviewing opportunities, and community meetings. As part of the GeoConnection Network, AGI hosts informational webinars to highlight new workforce data, discuss current affairs in the geosciences, and to provide information about geoscience careers. Between December 2009 and August 2010, AGI hosted 10 webinars, with more than 300 total participants for all the webinars, and 5 additional webinars are planned for the remainder of the year. The webinars offer early-career scientists the opportunity to understand global geoscience workforce concerns and to interact with geoscience professionals through question and answer sessions. Recordings of the live webinar presentations are posted online and may be accessed at any time.

Resources and Approaches for Teaching Quantitative and Computational Skills in the Geosciences and Allied Fields

NASA Astrophysics Data System (ADS)

Orr, C. H.; Mcfadden, R. R.; Manduca, C. A.; Kempler, L. A.

2016-12-01

Teaching with data, simulations, and models in the geosciences can increase many facets of student success in the classroom, and in the workforce. Teaching undergraduates about programming and improving students' quantitative and computational skills expands their perception of Geoscience beyond field-based studies. Processing data and developing quantitative models are critically important for Geoscience students. Students need to be able to perform calculations, analyze data, create numerical models and visualizations, and more deeply understand complex systems—all essential aspects of modern science. These skills require students to have comfort and skill with languages and tools such as MATLAB. To achieve comfort and skill, computational and quantitative thinking must build over a 4-year degree program across courses and disciplines. However, in courses focused on Geoscience content it can be challenging to get students comfortable with using computational methods to answers Geoscience questions. To help bridge this gap, we have partnered with MathWorks to develop two workshops focused on collecting and developing strategies and resources to help faculty teach students to incorporate data, simulations, and models into the curriculum at the course and program levels. We brought together faculty members from the sciences, including Geoscience and allied fields, who teach computation and quantitative thinking skills using MATLAB to build a resource collection for teaching. These materials, and the outcomes of the workshops are freely available on our website. The workshop outcomes include a collection of teaching activities, essays, and course descriptions that can help faculty incorporate computational skills at the course or program level. The teaching activities include in-class assignments, problem sets, labs, projects, and toolboxes. These activities range from programming assignments to creating and using models. The outcomes also include workshop syntheses that highlights best practices, a set of webpages to support teaching with software such as MATLAB, and an interest group actively discussing aspects these issues in Geoscience and allied fields. Learn more and view the resources at http://serc.carleton.edu/matlab_computation2016/index.html

Navigating the boundary of science for decision making at the state and local level

NASA Astrophysics Data System (ADS)

Gonzales, L. M.; Wood, C.; Boland, M. A.; Rose, C. A.

2015-12-01

Scientific information should play a vital role in many decision making processes, yet issues incorporating geoscience information often arise due to inherent differences between how scientists and decision makers operate. Decision makers and scientists have different priorities, produce work at different rates, and often lack an understanding of each others' institutional constraints. Boundary organizations, entities that facilitate collaboration and information flow across traditional boundaries such as that between scientists and decision makers, are in a unique position to improve the dialogue between disparate groups. The American Geosciences Institute (AGI), a nonprofit federation of 50 geoscience societies and organizations, is linking the geoscience and decision-making communities through its Critical Issues Program. AGI's Critical Issues program has first-hand experience in improving the transfer of information across the science-decision making boundary, particularly in areas pertaining to water resources and hazards. This presentation will focus on how, by collaborating with organizations representing the decision making and geoscience communities to inform our program development, we have created our three main content types - website, webinar series, and research database - to better meet the needs of the decision-making process. The program presents existing geoscience information in a way that makes the interconnected nature of geoscience topics more easily understood, encourages discussion between the scientific and decision-making communities, and has established a trusted source of impartial geoscience information. These efforts have focused on state and local decision makers—groups that increasingly influence climate and risk-related decisions, yet often lack the resources to access and understand geoscience information.

Exploring the Role of Information Professionals in Improving Research Reproducibility:A Case Study in Geosciences

NASA Astrophysics Data System (ADS)

Yan, A.; West, J.

2016-12-01

The validity of Geosciences research is of great significance to general public and policy-makers. In an earlier study, we surveyed 136 faculty and graduate students in geosciences. The result indicated that nearly 80% of respondents who had ever reproduced a published study had failed at least one time in reproducing, suggesting a general lack of research reproducibility in geosciences. Although there is much enthusiasm for creation of technologies such as workflow system, literate programming, and cloud-based system to facilitate reproducibility, much less emphasis has been placed on the information services essential for meaningful use of these tools. Library and Information Science (LIS) has a rich tradition of providing customized service for research communities. LIS professionals such as academic librarians have made strong contribution to resources locating, software recommending, data curation, metadata guidance, project management, submission review and author training. In particular, university libraries have been actively developing tools and offering guidelines, consultations, and trainings on Data Management Plan (DMP) required by National Science Foundation (NSF). And effective data management is a significant first step towards reproducible research. Hereby we argue that LIS professionals may be well-positioned to assist researchers to make their research reproducible. In this study, we aim to answer the question: how can LIS professionals assist geoscience researchers in making their research capable of being reproduced? We first synthesize different definitions of "reproducibility" and provide a conceptual framework of "reproducibility" in geosciences to resolve some of the misunderstandings around related terminology. Using a case study approach, we then examine 1) university librarians' technical skills, domain knowledge, professional activities, together with their awareness of, readiness for, and attitudes towards research reproducibility and 2) geosciences researcher needs for assistance in making research reproducible and attitude towards LIS services. The results of our study provide empirical evidence for an extension of library services, as well as for a potential solution in facilitating research reproducibility.

Undergraduate Research in Earth Science Classes: Engaging Students in the First Two Years

NASA Astrophysics Data System (ADS)

Mogk, D. W.; Wysession, M. E.; Beauregard, A.; Reinen, L. A.; Surpless, K.; O'Connell, K.; McDaris, J. R.

2014-12-01

The recent PCAST report (2012), Engage to Excel, calls for a major shift in instructional modes in introductory (geo)science courses by "replacing standard laboratory courses with discovery-based research courses". An increased emphasis is recommended to engage students in experiments with the possibility of true discovery and expanded use of scientific research courses in the first two years. To address this challenge, the On the Cutting Edge program convened a workshop of geoscience faculty to explore the many ways that true research experiences can be built into introductory geoscience courses. The workshop goals included: consideration of the opportunities, strategies and methods used to provide research experiences for students in lower division geoscience courses; examination of ways to develop students' "geoscience habits of mind" through participation in authentic research activities; exploration of ways that student research projects can be designed to contribute to public science literacy with applications to a range of issues facing humanity; and development of strategies to obtain funding for these research projects, to make these programs sustainable in departments and institutions, and to scale-up these programs so that all students may participate. Access to Earth data, information technology, lab and field-based instrumentation, and field experiences provide unprecedented opportunities for students to engage in authentic research at early stages in their careers. Early exposure to research experiences has proven to be effective in the recruitment of students to the geoscience disciplines, improved retention and persistence in degree programs, motivation for students to learn and increase self-efficacy, improved attitudes and values about science, and overall increased student success. Workshop outcomes include an online collection of tested research projects currently being used in geoscience classes, resources related to effective design, implementation and assessment of student research projects, and all workshop activities are posted on the website: http://serc.carleton.edu/74960

Addressing Issues of Broadening Participation Highlighted in the Report on the Future of Undergraduate Geoscience Education

NASA Astrophysics Data System (ADS)

McDaris, J. R.; Manduca, C. A.; Macdonald, H.; Iverson, E. A. R.

2015-12-01

The final report for the Summit on the Future of Geoscience Education lays out a consensus on issues that must be tackled by the geoscience community collectively if there are to be enough qualified people to fill the large number of expected geoscience job vacancies over the coming decade. Focus areas cited in the report include: Strengthening the connections between two-year colleges and four-year institutions Sharing and making use of successful recruitment and retention practices for students from underrepresented groups Making students aware of high-quality job prospects in the geosciences as well as its societal relevance The InTeGrate STEP Center for the Geosciences, the Supporting and Advancing Geoscience Education at Two-Year Colleges (SAGE 2YC) program, and the Building Strong Geoscience Departments (BSGD) project together have developed a suite of web resources to help faculty and program leaders begin to address these and other issues. These resources address practices that support the whole student, both in the classroom and as a part of the co-curriculum as well as information on geoscience careers, guidance for developing coherent degree programs, practical advice for mentoring and advising, and many others. In addition to developing web resources, InTeGrate has also undertaken an effort to profile successful program practices at a variety of institutions. An analysis of these data shows several common themes (e.g. proactive marketing, community building, research experiences) that align well with the existing literature on what works to support student success. But there are also indications of different approaches and emphases between Minority Serving Institutions (MSIs) and Primarily White Institutions (PWIs) as well as between different kinds of MSIs. Highlighting the different strategies in use can point both MSIs and PWIs to possible alternate solutions to the challenges their students face. InTeGrate - http://serc.carleton.edu/integrate/programs/diversity/index.html SAGE 2YC - http://serc.carleton.edu/sage2yc/index.html BSGD - http://serc.carleton.edu/NAGTWorkshops/departments/degree_programs/index.html

Teaching Geoethics Across the Geoscience Curriculum

NASA Astrophysics Data System (ADS)

Mogk, David; Bruckner, Monica; Kieffer, Susan; Geissman, John; Reidy, Michael; Taylor, Shaun; Vallero, Daniel

2015-04-01

Training in geoethics is an important part of pre-professional development of geoscientists. Professional societies, governmental agencies, and employers of the geoscience workforce increasingly expect that students have had some training in ethics to guide their professional lives, and the public demands that scientists abide by the highest standards of ethical conduct. The nature of the geosciences exposes the profession to ethical issues that derive from our work in a complex, dynamic Earth system with an incomplete geologic record and a high degree of uncertainty and ambiguity in our findings. The geosciences also address topics such as geohazards and resource development that have ethical dimensions that impact on the health, security, public policies, and economic well-being of society. However, there is currently no formal course of study to integrate geoethics into the geoscience curriculum and few faculty have the requisite training to effectively teach about ethics in their classes, or even informally in mentoring their research students. To address this need, an NSF-funded workshop was convened to explore how ethics education can be incorporated into the geoscience curriculum. The workshop addressed topics such as where and how should geoethics be taught in a range of courses including introductory courses for non-majors, as embedded modules in existing geoscience courses, or as a dedicated course for majors on geoethics; what are the best pedagogic practices in teaching ethics, including lessons learned from cognate disciplines (philosophy, biology, engineering); what are the goals for teaching geoethics, and what assessments can be used to demonstrate mastery of ethical principles; what resources currently exist to support teaching geoethics, and what new resources are needed? The workshop also explored four distinct but related aspects of geoethics: 1) Geoethics and self: what are the internal attributes of a geoscientist that establish the ethical values required to successfully prepare for and contribute to a career in the geosciences? 2) Geoethics and the geoscience profession: what are the ethical standards expected of geoscientists if they are to contribute responsibly to the community of practice expected of the profession? 3) Geoethics and society: what are the responsibilities of geoscientists to effectively and responsibly communicate the results of geoscience research to inform society about issues ranging from geohazards to natural resource utilization in order to protect the health, safety, and economic security of humanity? 4) Geoethics and Earth: what are the responsibilities of geoscientists to provide good stewardship of Earth based on their knowledge of Earth's composition, architecture, history, dynamic processes, and complex systems? Consideration of these components of geoethics will prepare students to recognize ethical dilemmas, and to master the skills needed for ethical decision-making in their professional lives. Collections of resources, case studies, presentations and working group summaries of the workshop can be accessed at: http://serc.carleton.edu/geoethics/index.html

Identifying Curriculum Design Patterns as a Strategy for Focusing Geoscience Education Research: A Proof of Concept Based on Teaching and Learning with Geoscience Data

ERIC Educational Resources Information Center

Kastens, Kim; Krumhansl, Ruth

2017-01-01

The geoscience education research (GER) enterprise faces a challenge in moving instructional resources and ideas from the well-populated domain of "practitioners' wisdom" into the research-tested domains of St. John and McNeal's pyramid of evidence (this volume). We suggest that the process could be accelerated by seeking out clusters of…

Geoscience and Public Policy

NASA Astrophysics Data System (ADS)

White, K. S.

2013-12-01

Many current public policy issues have a geoscience component: climate change, natural hazards, energy, and mineral resources to name just a few. In addition, Congress makes decisions that directly affect scientists, such as funding allocations and visa and travel policy. Yet few geoscientists are engaged in the policy-making process. Members of Congress have called on scientists to become more active, including Ph.D. physicist and former-Representative Vernon Ehlers (R-MI). In an address at the 2010 AAAS Forum on Science and Technology Policy, he told scientists, "The gulf between the scientifically minded and those who are not scientifically minded is still tremendous. I think we are keeping far too quiet about what we know and how we would go about solving problems. We have so much to offer this country à solutions to various difficulties." This talk will provide information on avenues for geoscientists to more effectively engage in the public policy arena.

SAS- Semantic Annotation Service for Geoscience resources on the web

NASA Astrophysics Data System (ADS)

Elag, M.; Kumar, P.; Marini, L.; Li, R.; Jiang, P.

2015-12-01

There is a growing need for increased integration across the data and model resources that are disseminated on the web to advance their reuse across different earth science applications. Meaningful reuse of resources requires semantic metadata to realize the semantic web vision for allowing pragmatic linkage and integration among resources. Semantic metadata associates standard metadata with resources to turn them into semantically-enabled resources on the web. However, the lack of a common standardized metadata framework as well as the uncoordinated use of metadata fields across different geo-information systems, has led to a situation in which standards and related Standard Names abound. To address this need, we have designed SAS to provide a bridge between the core ontologies required to annotate resources and information systems in order to enable queries and analysis over annotation from a single environment (web). SAS is one of the services that are provided by the Geosematnic framework, which is a decentralized semantic framework to support the integration between models and data and allow semantically heterogeneous to interact with minimum human intervention. Here we present the design of SAS and demonstrate its application for annotating data and models. First we describe how predicates and their attributes are extracted from standards and ingested in the knowledge-base of the Geosemantic framework. Then we illustrate the application of SAS in annotating data managed by SEAD and annotating simulation models that have web interface. SAS is a step in a broader approach to raise the quality of geoscience data and models that are published on the web and allow users to better search, access, and use of the existing resources based on standard vocabularies that are encoded and published using semantic technologies.

Unlocking the Treasures of the Ocean: Current Assessment and Future Perspectives of Seafloor Resources (C.F Gauss Lecture)

NASA Astrophysics Data System (ADS)

Jegen, Marion

2016-04-01

Oceans cover 70% of the Earth's surface, and there is reason to believe that the wealth of mineral and carbon resources on the seafloor is similar to deposits on land. While off-shore energy resources such as oil and gas are nowadays regarded as conventional, energy resources in form of methane hydrates and seafloor mineral deposits are yet unconventional and at best marginally economic. However, taking into account global population growth, geopolitics and technological development (both in terms of increasing industrialization and possibility to explore and mine seafloor resources), these resources might play a more fundamental role in the future. Resource assessment and understanding of the geological formation process of resources are topics in marine geosciences with broad relevance to society. The lecture presents an overview of the geophysical exploration of the seafloor and its resource potential. Starting from the link of physical parameter anomalies associated with resources, I will explore marine technological developments on how to sense them remotely from the seafloor. Also the question will be addressed of how well we can actually quantify the amount of resources from geophysical data. The process will be illustrated based on theoretical work as well as case studies from around the world.

Activities for Plate Tectonics using GeoMapApp

NASA Astrophysics Data System (ADS)

Goodwillie, A. M.

2016-12-01

The concept of plate tectonics is a fundamental component of our understanding of how Earth works yet authentic, high-quality geoscience data related to plate tectonics may not be readily available to all students. To compound matters, when data is accessible, students may not possess the skills or resources necessary to explore and analyse it. As a result, much emphasis at federal and state level is now placed upon encouraging students to work with more data and more technology more often and more rigourously. Easy-to-use digital platforms offer much potential for promoting inquiry-based learning at all levels of education. GeoMapApp is one such tool. Developed at Columbia University's Lamont-Doherty Earth Observatory, GeoMapApp (http://www.geomapapp.org) is a free resource that integrates a wide range of research-grade geoscience data in one intuitive map-based interface. Simple strategies for data manipulation, visualisation and presentation allow uses to explore the data in meaningful ways. Layering and transparency capabilities further allow learners to use GeoMapApp to compare multiple data sets at once, and high-impact Save Session functionality allows a GeoMapApp project to be saved for sharing or later use. In this presentation, activities related to plate tectonics will be highlighted. One GeoMapApp activity helps students investigate plate boundaries by exploring earthquake and volcano locations. Another requires students to calculate the rate of seafloor spreading using crustal age data in various ocean basins. A third uses the GeoMapApp layering technique to explore the influence of geological forces in shaping the landscape. Each activity shown can be done by students on an individual basis, as pairs, or as groups. Educators report that student use of GeoMapApp fosters an increased sense of data "ownership" amongst students, promotes STEM skills, and provides them with access to authentic research-grade geoscience data using the same cutting-edge technological tool used by researchers.

Design of Community Resource Inventories as a Component of Scalable Earth Science Infrastructure: Experience of the Earthcube CINERGI Project

NASA Astrophysics Data System (ADS)

Zaslavsky, I.; Richard, S. M.; Valentine, D. W., Jr.; Grethe, J. S.; Hsu, L.; Malik, T.; Bermudez, L. E.; Gupta, A.; Lehnert, K. A.; Whitenack, T.; Ozyurt, I. B.; Condit, C.; Calderon, R.; Musil, L.

2014-12-01

EarthCube is envisioned as a cyberinfrastructure that fosters new, transformational geoscience by enabling sharing, understanding and scientifically-sound and efficient re-use of formerly unconnected data resources, software, models, repositories, and computational power. Its purpose is to enable science enterprise and workforce development via an extensible and adaptable collaboration and resource integration framework. A key component of this vision is development of comprehensive inventories supporting resource discovery and re-use across geoscience domains. The goal of the EarthCube CINERGI (Community Inventory of EarthCube Resources for Geoscience Interoperability) project is to create a methodology and assemble a large inventory of high-quality information resources with standard metadata descriptions and traceable provenance. The inventory is compiled from metadata catalogs maintained by geoscience data facilities, as well as from user contributions. The latter mechanism relies on community resource viewers: online applications that support update and curation of metadata records. Once harvested into CINERGI, metadata records from domain catalogs and community resource viewers are loaded into a staging database implemented in MongoDB, and validated for compliance with ISO 19139 metadata schema. Several types of metadata defects detected by the validation engine are automatically corrected with help of several information extractors or flagged for manual curation. The metadata harvesting, validation and processing components generate provenance statements using W3C PROV notation, which are stored in a Neo4J database. Thus curated metadata, along with the provenance information, is re-published and accessed programmatically and via a CINERGI online application. This presentation focuses on the role of resource inventories in a scalable and adaptable information infrastructure, and on the CINERGI metadata pipeline and its implementation challenges. Key project components are described at the project's website (http://workspace.earthcube.org/cinergi), which also provides access to the initial resource inventory, the inventory metadata model, metadata entry forms and a collection of the community resource viewers.

The Geoscience Alliance--A National Network for Broadening Participation of Native Americans in the Geosciences

NASA Astrophysics Data System (ADS)

Dalbotten, D. M.; Berthelote, A. R.

2014-12-01

The Geoscience Alliance is a national alliance of individuals committed to broadening participation of Native Americans in the geosciences. Native Americans in this case include American Indians, Alaska Natives and people of Native Hawai'ian ancestry. Although they make up a large percentage of the resource managers in the country, they are underrepresented in degrees in the geosciences. The Geoscience Alliance (GA) members are faculty and staff from tribal colleges, universities, and research centers; native elders and community members; industry, agency, and corporate representatives; students (K12, undergraduate, and graduate); formal and informal educators; and other interested individuals. The goals of the Geoscience Alliance are to 1) create new collaborations in support of geoscience education for Native American students, 2) establish a new research agenda aimed at closing gaps in our knowledge on barriers and best practices related to Native American participation in the geosciences, 3) increase participation by Native Americans in setting the national research agenda on issues in the geosciences, and particularly those that impact Native lands, 4) provide a forum to communicate educational opportunities for Native American students in the geosciences, and 5) to understand and respect indigenous traditional knowledge. In this presentation, we look at the disparity between numbers of Native Americans involved in careers related to the geosciences and those who are receiving bachelors or graduate degrees in the geosciences. We address barriers towards degree completion in the geosciences, and look at innovative programs that are addressing those barriers.

Getting to our Big Data Future: A 'How To' Guide for Producers and Users

NASA Astrophysics Data System (ADS)

Diggs, S. C.

2015-12-01

The informatics community is currently making the promise of a 'Big Data' future a reality, but the array of terms, technologies and personnel can be daunting. If your world is FORTRAN and FTP, how can you exploit Python, Semantically Linked Data and data center APIs? How can the scientist in the field take part in this cyber-revolution and go beyond data websites for discovery, access, data use? The Geoscience community needs a resource that explains what Big Data technologies are, how we got here, why we are here, why you should get involved, and who is out there to help.

Geoscience in Developing Countries of South Asia and International Cooperation

NASA Astrophysics Data System (ADS)

Gupta, K.

2007-12-01

Earth Science community in developing countries of South Asia is actively engaged in interdisciplinary investigations of the Earth and its envelopes through geological, geophysical and geochemical processes, for these processes are interconnected. Interdisciplinary interaction will continue to grow since problems pertaining to the solid earth, with its core-mantle-crust, and fluid envelops can be solved only with contributions from different Science disciplines. The expanding population and revolution in data handling-and-computing have now become a necessity to tackle the geoscientific problems with modern techniques and methodologies to meet these new challenges. As a future strategy, geo-data generation and handling need to be speedier and easier and hence demands a well- knit coordiantion and understanding amongst Governments, Industries and Academic organizations. Such coordination will prove valuable for better understanding of the Earth's processes, especially mitigating natural hazards with more accurate and speedy prdictions, besides sustaining Earth's resources. South Asian geoscience must, therefore, seek new directions by way of strategies, policies, and actions to move forward in this century. Environmental and resource problems affecting the world population have become international issues, since global environmental changes demand international cooperation and planning. The Earth is continually modified by the interplay of internal and external processes. Hence we need to apply modern geophysical techniques and interpret the results with the help of available geological, geochronological and gechemical informations It is through such integrated approach that we could greatly refine our understanding of the deep structure and evolution of the Indian shield. However, the inputs into multi-disciplinary studies necessary to know the crustal structure and tectonics in the adjoining regions (Nepal, Bangladesh, Myanmar, Sri Lanka etc.) still remain subcritical. With this realization, it is suggested that there is a need for joint collaboration to undertake integrated geoscientific studies in the contiguous regions/ countries to understand the evolutionary and dynamical aspects, especially of Himalayan orogenic belt, monsoon variability and geodynamics of the Indian shield & adjoining regions. The focus of our future cooperation in geosciences education and research in developing countries of South Asia must have substantial inputs in the area of sound environmental management, climate change, natural hazards, risk evaluation, water resources, and interfacing of geological and agricultural sciences, etc. At the same time our long term activities around geological resources, particularly energy and mineral resources, need to be pursued in a synergetic mode. It is necessary to have a viable mechanism to identify areas of mutual collaboration in geosciences ( including manpower development, use of analytical instrumental facilities, IT & communication technologies ) to explore the possibility of inter-institutional linkages in Earth System Science in developing countries of South Asia. The issues related to effective international cooperation in geosciences in South Asian countries and the role of individuals, academic institutions, funding agencies, and scientific societies in consolidating and improving research and education have been discussed .

Developing Technologies for Space Resource Utilization: Concept for a Planetary Engineering Research Institute

NASA Astrophysics Data System (ADS)

Blacic, J. D.; Dreesen, D.; Mockler, T.

2000-01-01

There are two principal factors that control the economics and ultimate utilization of space resources: 1) space transportation, and 2) space resource utilization technologies. Development of space transportation technology is driven by major government (military and civilian) programs and, to a lesser degree, private industry-funded research. Communication within the propulsion and spacecraft engineering community is aided by an effective independent professional organization, the American Institute of Aeronautics and Astronautics (AIAA). The many aerospace engineering programs in major university engineering schools sustain professional-level education in these fields. NASA does an excellent job of public education in space science and engineering at all levels. Planetary science, a precursor and supporting discipline for space resource utilization, has benefited from the establishment of the Lunar and Planetary Institute (LPI) which has served, since the early post-Apollo days, as a focus for both professional and educational development in the geosciences of the Moon and other planets. The closest thing the nonaerospace engineering disciplines have had to this kind of professional nexus is the sponsorship by the American Society of Civil Engineers of a series of space engineering conferences that have had a predominantly space resource orientation. However, many of us with long-standing interests in space resource development have felt that an LPI-like, independent institute was needed to focus and facilitate both research and education on the specific engineering disciplines needed to develop space resource utilization technologies on an on-going basis.

Intersection of Hip-Hop and Geoscience: Changes in The Climate

NASA Astrophysics Data System (ADS)

López, R. D.; Heraldo, S. E.; Nawman, M. A.; Gerry, V. R.; Gerry, M. A.

2017-12-01

Professionals and educators in the science, technology, engineering, art, and mathematics (STEAM) field rely heavily on scientific communication to convey innovations, concepts, and evidence-based policy. The geosciences presents itself as a unique field to communicate respective scientific endeavors, as research efforts have direct impacts on the Earth's resources and understanding natural processes. Several of the authors have previously composed musical pieces that integrated Earth Sciences with music, utilizing this as mechanism to not only foster creativity, but to also establish more dynamic outreach efforts. Unfortunately, geoscience does not readily present itself as a field that is easily accessible to minorities - particularly women, people of color, and those from disadvantaged communities. However, music is somewhat of a universal form of communication that is accessible to everyone. It is through the intersection of hip-hop and geoscience, that topics can be introduced to communities in unique ways. Flows in Hydrogeology was a previous project that several of the authors produced as a means to connect with youth who identify with the hip-hop community, while encouraging inquiry in the STEAM fields. Several of the authors grew up and still reside in some of the most violent cities in the United States of America. The authors have utilized their respective backgrounds in both upbringing and career endeavors to help bridge the gap between science and disadvantaged communities. The musical piece, Changes in the Climate, illustrates the power of understanding the changes in one's life and surrounding world via delivery of concepts with hip-hop and rap. Therefore this musical composition not only integrates STEAM and music, but also serves as mechanism for outreach and encouraging diversity. Such actions could yield the success of accessing untapped potential, while fostering unique opportunities for future collaboration between professionals in geoscience and youth from various communities.

Translational Geoscience: Converting Geoscience Innovation into Societal Impacts

NASA Astrophysics Data System (ADS)

Schiffries, C. M.

2015-12-01

Translational geoscience — which involves the conversion of geoscience discovery into societal, economic, and environmental impacts — has significant potential to generate large benefits but has received little systematic attention or resources. In contrast, translational medicine — which focuses on the conversion of scientific discovery into health improvement — has grown enormously in the past decade and provides useful models for other fields. Elias Zerhouni [1] developed a "new vision" for translational science to "ensure that extraordinary scientific advances of the past decade will be rapidly captured, translated, and disseminated for the benefit of all Americans." According to Francis Collins, "Opportunities to advance the discipline of translational science have never been better. We must move forward now. Science and society cannot afford to do otherwise." On 9 July 2015, the White House issued a memorandum directing U.S. federal agencies to focus on translating research into broader impacts, including commercial products and decision-making frameworks [3]. Natural hazards mitigation is one of many geoscience topics that would benefit from advances in translational science. This paper demonstrates that natural hazards mitigation can benefit from advances in translational science that address such topics as improving emergency preparedness, communicating life-saving information to government officials and citizens, explaining false positives and false negatives, working with multiple stakeholders and organizations across all sectors of the economy and all levels of government, and collaborating across a broad range of disciplines. [1] Zerhouni, EA (2005) New England Journal of Medicine 353(15):1621-1623. [2] Collins, FS (2011) Science Translational Medicine 3(90):1-6. [3] Donovan, S and Holdren, JP (2015) Multi-agency science and technology priorities for the FY 2017 budget. Executive Office of the President of the United States, 5 pp.

GOLD (GEO Opportunities for Leadership in Diversity): Building capacity for broadening participation in the Geosciences

NASA Astrophysics Data System (ADS)

Jones, B.; Patino, L. C.; Rom, E. L.; Adams, A.

2017-12-01

The geosciences continue to lag other science, technology, engineering, and mathematics (STEM) disciplines in the engagement, recruitment and retention of traditionally underrepresented and underserved groups, requiring more focused and strategic efforts to address this problem. Prior investments made by the National Science Foundation (NSF) related to broadening participation in STEM have identified many effective strategies and model programs for engaging, recruiting, and retaining underrepresented students in the geosciences. These investments also have documented clearly the importance of committed, knowledgeable, and persistent leadership for making local progress in this area. Achieving diversity at larger and systemic scales requires a network of diversity "champions" who can catalyze widespread adoption of these evidence-based best practices and resources. Although many members of the geoscience community are committed to the ideals of broadening participation, the skills and competencies to achieve success must be developed. The NSF GEO Opportunities for Leadership in Diversity (GOLD) program was implemented in 2016, as a funding opportunity utilizing the Ideas Lab mechanism. Ideas Labs are intensive workshops focused on finding innovative solutions to grand challenge problems. The ultimate aim of this Ideas Lab, organized by the NSF Directorate for Geosciences (GEO), was to facilitate the design, pilot implementation, and evaluation of innovative professional development curricula that can unleash the potential of geoscientists with interests in broadening participation to become impactful leaders within the community. The expectation is that mixing geoscientists with experts in broadening participation research, behavioral change, social psychology, institutional change management, leadership development research, and pedagogies for professional development will not only engender fresh thinking and innovative approaches for preparing and empowering geoscientists as change agents for increasing diversity, but will also produce experiments that contribute to the research base regarding leader and leadership development.

Choosing the Geoscience Major: Important Factors, Race/Ethnicity, and Gender

ERIC Educational Resources Information Center

Stokes, Philip J.; Levine, Roger; Flessa, Karl W.

2015-01-01

Geoscience faces dual recruiting challenges: a pending workforce shortage and a lack of diversity. Already suffering from low visibility, geoscience does not resemble the makeup of the general population in terms of either race/ethnicity or gender and is among the least diverse of all science, technology, engineering, and math fields in the U.S.…

Programming and Technology for Accessibility in Geoscience

NASA Astrophysics Data System (ADS)

Sevre, E.; Lee, S.

2013-12-01

Many people, students and professors alike, shy away from learning to program because it is often believed to be something scary or unattainable. However, integration of programming into geoscience education can be a valuable tool for increasing the accessibility of content for all who are interested. It is my goal to dispel these myths and convince people that: 1) Students with disabilities can use programming to increase their role in the classroom, 2) Everyone can learn to write programs to simplify daily tasks, 3) With a deep understanding of the task, anyone can write a program to do a complex task, 4) Technology can be combined with programming to create an inclusive environment for all students of geoscience, and 5) More advanced knowledge of programming and technology can lead geoscientists to create software to serve as assistive technology in the classroom. It is my goal to share my experiences using technology to enhance the classroom experience as a way of addressing the aforementioned issues. Through my experience, I have found that programming skills can be included and learned by all to enhance the content of courses without detracting from curriculum. I hope that, through this knowledge, geoscience courses can become more accessible for people with disabilities by including programming and technology to the benefit of all involved.

Ka`Imi`Ike: Explorations in the Geosciences from an Indigenous Perspective

NASA Astrophysics Data System (ADS)

Gibson, B. A.; Puniwai, N.; Sing, D.; Ziegler-Chong, S.

2006-12-01

The Ka `Imi `Ike Program is a recent initiative at the University of Hawai`i whose mission is to recruit and retain Native Hawaiian and Pacific Islanders (NHPI) to disciplines within the geosciences. The Program seeks to create pathways for NHPI students interested in geoscience disciplines through various venues and activities, including linking science with culture and community through a summer boarding experience for incoming freshman or sophomore University of Hawaii students. The 3-week institute, Explorations in Geosciences, was offered for the first time in Summer 2006. The 10 college students who participated were introduced to mentor geoscientists to learn more about the different disciplines and the pathways the scientists took in their careers. Hands-on activities trained students in current technology (such as GPS) and exposed them to how the technology was used in different research applications. A key and crucial component of the Explorations in Geosciences summer program was that "local" or Native Hawaiian role models were selected as the geoscience mentors whenever possible and mostly local and regional examples of geoscience phenomena were used. Moreover, the "science" learned throughout the summer program was linked to local Traditional Environmental Knowledge (TEK) by a Native Hawaiian kumu (teacher). The merging of "western" science with traditional knowledge reinforced geoscience concepts, and afforded the students an opportunity to better understand how a career in the geosciences could be beneficial to them and their community. At the end of the summer institute, the students had to give a final presentation of what geoscience concepts and careers they thought were most interesting to them, and how the program impacted their view of the geosciences. They also had to keep a daily journal which outlined their thoughts about the topics presented each day of the summer institute. Preliminary assessment reveals that several of the students came away from the summer program with a better understanding of the geosciences and are now considering a possible career in a geoscience discipline. The students also indicated that the linking of traditional knowledge with "western" science strengthened their perception of how the geosciences are a part of their cultural understanding of the environmental.

Native Geosciences: Pathways to Traditional Knowledge in Modern Research and Education

NASA Astrophysics Data System (ADS)

Bolman, J. R.

2010-12-01

Native people have lived for millennia in distinct and unique ways in our natural sacred homelands and environments. Tribal cultures are the expression of deep understandings of geosciences shared through oral histories, language, traditional practices and ceremonies. Today, Native people as all people are living in a definite time of change. The developing awareness of "change" brings forth an immense opportunity to expand, elevate and incorporate Traditional Native geosciences knowledge into modern research and education to expand understandings for all learners. At the center of "change" is the need to balance the needs of the people with the needs of the environment. Native traditions and our inherent understanding of what is "sacred above is sacred below" is the foundation for a multi-faceted approach for increasing the representation of Natives in geosciences. The approach is centered on the incorporation of traditional knowledge into modern research/education. The approach is also a pathway to assist in Tribal language revitalization, connection of oral histories and ceremonies to place and building an intergenerational teaching/learning community. Humboldt State University, Sinte Gleska University and Tribes in Northern California (Hoopa, Yurok, & Karuk) and Great Plains (Lakota) Tribes have nurtured Native geosciences learning and research communities connected to Tribal Sacred Sites and natural resources. Native geoscience learning is centered on the themes of earth, wind, fire and water and the Native application of remote sensing technologies. Tribal Elders and Native geoscientists work collaboratively providing Native families in-field experiential intergenerational learning opportunities which invite participants to immerse themselves spiritually, intellectually, physically and emotionally in the experiences. Through this immersion and experience Native students and families strengthen the circle of our future Tribal communities and a return to traditional ways of supporting the development of our "story" or purpose for being. The opportunities include residential summer field experiences, interdisciplinary curriculums and development of Tribally-driven Native research/education experiences.

GOLD: Building capacity for broadening participation in the Geosciences

NASA Astrophysics Data System (ADS)

Adams, Amanda; Patino, Lina; Jones, Michael B.; Rom, Elizabeth

2017-04-01

The geosciences continue to lag other science, technology, engineering, and mathematics (STEM) disciplines in the engagement, recruitment and retention of traditionally underrepresented and underserved minorities, requiring more focused and strategic efforts to address this problem. Prior investments made by the National Science Foundation (NSF) related to broadening participation in STEM have identified many effective strategies and model programs for engaging, recruiting, and retaining underrepresented students in the geosciences. These investments also have documented clearly the importance of committed, knowledgeable, and persistent leadership for making local progress in broadening participation in STEM and the geosciences. Achieving diversity at larger and systemic scales requires a network of diversity "champions" who can catalyze widespread adoption of these evidence-based best practices and resources. Although many members of the geoscience community are committed to the ideals of broadening participation, the skills and competencies that empower people who wish to have an impact, and make them effective as leaders in that capacity for sustained periods of time, must be cultivated through professional development. The NSF GEO Opportunities for Leadership in Diversity (GOLD) program was implemented in 2016, as a funding opportunity utilizing the Ideas Lab mechanism. Ideas Labs are intensive workshops focused on finding innovative solutions to grand challenge problems. The ultimate aim of this Ideas Lab, organized by the NSF Directorate for Geosciences (GEO), was to facilitate the design, pilot implementation, and evaluation of innovative professional development curricula that can unleash the potential of geoscientists with interests in broadening participation to become impactful leaders within the community. The expectation is that mixing geoscientists with experts in broadening participation research, behavioral change, social psychology, institutional change management, leadership development research, and pedagogies for professional development will not only engender fresh thinking and innovative approaches for preparing and empowering geoscientists as change agents for increasing diversity, but will also produce experiments that contribute to the research base regarding leader and leadership development.

An Integrated Model for Improving Undergraduate Geoscience Workforce Readiness

NASA Astrophysics Data System (ADS)

Keane, C. M.; Houlton, H. R.

2017-12-01

Within STEM fields, employers are reporting a widening gap in the workforce readiness of new graduates. As departments continue to be squeezed with new requirements, chasing the latest technologies and scientific developments and constrained budgets, formal undergraduate programs struggle to fully prepare students for the workforce. One major mechanisms to address gaps within formal education is in life-long learning. Most technical and professional fields have life-long learning requirements, but it is not common in the geosciences, as licensing requirements remain limited. By introducing the concept of career self-management and life-long learning into the formal education experience of students, we can build voluntary engagement and shift some of the preparation burden from existing degree programs. The Geoscience Online Learning Initiative (GOLI) seeks to extend professional life-long learning into the formal education realm. By utilizing proven, effective means to capture expert knowledge, the GOLI program constructs courses in the OpenEdX platform, where the content authors and society staff continuously refine the material into effective one- to two-hour long asynchronous modules. The topical focus of these courses are outside of the usual scope of the academic curriculum, but are aligned with applied technical or professional issues. These courses are provided as open education resources, but also qualify for CEUs as the ongoing professional microcredential in the profession. This way, interested faculty can utilize these resources as focused modules in their own course offerings or students can engage in the courses independently and upon passing the assessments and paying of a nominal fee, be awarded CEUs which count towards their professional qualifications. Establishing a continuum of learning over one's career is a critical cultural change needed for students to succeed and be resilient through the duration of a career. We will examine how this approach mimics successful efforts in other STEM fields and where it aligns with both ongoing evolution in professional geoscience employment and broader trends in STEM career management.

The Person Behind the Picture: Influence of Social and Cultural Capital on Geoscience Career Pathways

NASA Astrophysics Data System (ADS)

Rappolee, E.; Libarkin, J. C.; McCallum, C.; Kurz, S.

2017-12-01

The amalgamation of fields in the geosciences share one desire: a better understanding of the natural world and the relationship humans have with that world. As issues such as climate change and clean water become globally recognized the geoscience job market grows. To insure these issues are resolved in ways that are fully representative of the entire human population, attention has been turned to increasing diversity of scientists in the geosciences. This study is based in the theory of social and cultural capital, types of non-financial wealth obtained by individuals and groups through connections and experiences. In particular, we investigated how individuals accessed specific resources and opportunities which eventually led to their entering the geosciences. Surveys were distributed to volunteers at a multinational geoscience conference held in fall of 2016. These surveys asked participants to "draw a picture of the people and experiences that have influenced your career up to this point." Nearly 150 completed drawings were coded through a thematic content analysis, wherein salient characteristics of drawings were documented and later grouped into common themes. We found that specific people (family, professors, peers) provided access to resources (education, museums, parks) as well as experiences (camping, traveling, research) that were instrumental in career building. Correlation analysis revealed two representative models of the drawings. These models aligned with the constructs of social and cultural capital. Cultural capital was more prevalent in majority white than nonwhite participants, suggesting different pathways into geoscience careers. We hope this research will inspire future work as well as highlight ways in which social and cultural capital can become accessible to future generations to produce a system with equal opportunities and increase diversity in the geosciences, resulting in better decision-making on global issues.

Geoscience as an Agent for Change in Higher Education

NASA Astrophysics Data System (ADS)

Manduca, C. A.; Orr, C. H.; Kastens, K.

2016-12-01

As our society becomes more aware of the realities of the resource and environmental challenges that face us, we have the opportunity to educate more broadly about the role of geoscience in addressing these challenges. The InTeGrate STEP Center is using three strategies to bring learning about the Earth to a wider population of undergraduate students: 1) infusing geoscience into disciplinary courses throughout the curriculum; 2) creating interdisciplinary or transdisciplinary courses with a strong geoscience component that draw a wide audience; and 3) embedding more opportunities to learn about the methods of geoscience and their application to societal challenges in courses for future teachers. InTeGrate is also bringing more emphasis on geoscience in service to societal challenges to geoscience students in introductory geoscience courses and courses for geoscience majors. Teaching science in a societal context is known to make science concepts more accessible for many learners, while learning to use geoscience to solve real world, interdisciplinary problems better prepares students for the 21stcentury workforce and for the decisions they will make as individuals and citizens. InTeGrate has developed materials and models that demonstrate a wide variety of strategies for increasing opportunities to learn about the Earth in a societal context that are freely available on the project website (http://serc.carleton.edu/integrate) and that form the foundation of ongoing professional development opportunities nationwide. The strategies employed by InTeGrate reflect a systems approach to educational transformation, the importance of networks and communities in supporting change, and the need for resources designed for adaptability and use. The project is demonstrating how geoscience can play a larger role in higher education addressing topics of wide interest including 1) preparing a competitive workforce by increasing the STEM skills of students regardless of their major, 2) making higher education more equitable by reducing gaps in participation and achievement in STEM; and 3) using liberal education to prepare students to deal with the complexity, diversity and change that characterize our time.

Portrayal of the Geosciences in the New York Times

NASA Astrophysics Data System (ADS)

Wysession, M. E.; Lindstrom, A.

2017-12-01

An analysis of the portrayal of science, including the geosciences, in the New York Times shows that geoscience topics dominate front-page science coverage, appearing significantly more often than articles concerning biology, chemistry, or physics. This is significant because the geosciences are sometimes portrayed (in most high schools, for example) as being of less significance or importance than the other sciences, yet their portrayal in what is arguably the leading U.S. newspaper shows just the opposite - that the geosciences are the most relevant and newsworthy of the sciences. We analyzed NY Times front pages and Tuesday "Science Times" sections for 2012 - 2015, and looked at many parameters including science discipline, the kind of article (research, policy, human-interest, etc.), correlations to the "big ideas" of the Next Generation Science Standards, and for the geosciences, a break-down of sub-disciplines. For the front pages, we looked at both full articles and call-outs to articles on later pages. For front-page full articles, geoscience-related articles were more frequent (almost 60%) than biology, chemistry, and physics combined. Including call-outs to later articles, the geosciences still made the most front-page appearances (almost 40%), and this included the fact that 1/3 of front-page science articles were medicine-related, which accounted for nearly all of the biology and chemistry articles. Interestingly, what the NY Times perceived as "science" differed significantly: 60% of all Tuesday "Science Times" articles were medicine-related, and even removing these, biology (40%) edged the geosciences (35%) as the most frequent Science Times articles. Of the front-page geoscience articles, the topics were dominated each year by natural hazards, natural resources, and human impacts, with the percentage of human-impact-related articles almost doubling over the 4 years. The most significant 4-year trend was in the attention paid to climate change. For example, between 2012-2015, the number of articles dealing with energy resources remained roughly constant (22% to 26%), but the number of climate change-related articles grew significantly, going from 6% of all geoscience articles to 27%.

Tackling Strategies for Thriving Geoscience Departments

NASA Astrophysics Data System (ADS)

Wuebbles, Donald J.; Takle, Eugene S.

2005-05-01

Special sessions on thriving geosciences departments and on cyberinfrastructure in the geosciences highlighted the recent 5th AGU Meeting of Heads and Chairs of Earth and Space Science Departments. ``From Surviving to Thriving: Strategies for Advancing University Geoscience Programs in Times of Change'' was a topic that drew intense interest. This panel discussion, led by Don Wuebbles (University of Illinois), included panelists Eric Betterton (University of Arizona), Judy Curry (Georgia Institute of Technology), Heather MacDonald (College of William and Mary), and Jim Kirkpatrick (University of Illinois).

National Association of Geoscience Teachers (NAGT) support for the Next Generation Science Standards

NASA Astrophysics Data System (ADS)

Buhr Sullivan, S. M.; Awad, A. A.; Manduca, C. A.

2014-12-01

The Next Generation Science Standards (NGSS) represents the best opportunity for geosciences education since 1996, describing a vision of teaching excellence and placing Earth and space science on a par with other disciplines. However, significant, sustained support and relationship-building between disciplinary communities must be forthcoming in order to realize the potential. To realize the vision, teacher education, curricula, assessments, administrative support and workforce/college readiness expectations must be developed. The National Association of Geoscience Teachers (NAGT), a geoscience education professional society founded in 1938, is comprised of members across all educational contexts, including undergraduate faculty, pre-college teachers, informal educators, geoscience education researchers and teacher educators. NAGT support for NGSS includes an upcoming workshop in collaboration with the American Geosciences Institute, deep collections of relevant digital learning resources, pertinent interest groups within the membership, professional development workshops, and more. This presentation will describe implications of NGSS for the geoscience education community and highlight some opportunities for the path forward.

An Integrated Strategy for Promoting Geoscience Education and Research in Developing Countries through International Cooperation

NASA Astrophysics Data System (ADS)

Aswathanarayana, U.

2007-12-01

Geoscience education and research in Developing countries should aim at achieving food, water and environmental security, and disaster preparedness, based on the synergetic application of earth (including atmospheric and oceanic realms), space and information sciences through economically-viable, ecologically- sustainable and people-participatory management of natural resources. The proposed strategy involves the integration of the following three principal elements: (i) What needs to be taught: Geoscience needs to be taught as earth system science incorporating geophysical, geochemical and geobiological approaches, with focus (say, 80 % of time) on surficial processes (e.g. dynamics of water, wind and waves, surface and groundwater, soil moisture, geomorphology, landuse, crops), and surficial materials (e.g. soils, water, industrial minerals, sediments, biota). Subjects such as the origin, structure and evolution of the earth, and deep-seated processes (e.g. dynamics of the crust-mantle interaction, plate tectonics) could be taught by way of background knowledge (say, 20 % of the time), (ii) How jobs are to be created: Jobs are to be created by merging geoscience knowledge with economic instruments (say, micro enterprises), and management structures at different levels (Policy level, Technology Transfer level and Implementation level), customized to the local biophysical and socioeconomic situations, and (iii) International cooperation: Web-based instruction (e.g. education portals, virtual laboratories) through South - South and North - South cooperation, customized to the local biophysical and socioeconomic situations, with the help of (say) UNDP, UNESCO, World Bank, etc.

Designing and Using Videos in Undergraduate Geoscience Education - a workshop and resource website review

NASA Astrophysics Data System (ADS)

Wiese, K.; Mcconnell, D. A.

2014-12-01

Do you use video in your teaching? Do you make your own video? Interested in joining our growing community of geoscience educators designing and using video inside and outside the classroom? Over four months in Spring 2014, 22 educators of varying video design and development expertise participated in an NSF-funded On the Cutting Edge virtual workshop to review the best educational research on video design and use; to share video-development/use strategies and experiences; and to develop a website of resources for a growing community of geoscience educators who use video: http://serc.carleton.edu/NAGTWorkshops/video/workshop2014/index.html. The site includes links to workshop presentations, teaching activity collections, and a growing collection of online video resources, including "How-To" videos for various video editing or video-making software and hardware options. Additional web resources support several topical themes including: using videos to flip classes, handling ADA access and copyright issues, assessing the effectiveness of videos inside and outside the classroom, best design principles for video learning, and lists and links of the best videos publicly available for use. The workshop represents an initial step in the creation of an informal team of collaborators devoted to the development and support of an ongoing network of geoscience educators designing and using video. Instructors who are interested in joining this effort are encouraged to contact the lead author.

Field Test of a Peer Review System for Digital Geoscience Education Resources

NASA Astrophysics Data System (ADS)

Mayhew, M. A.; Hall, M. K.

2007-12-01

We report the results of an experiment aimed at developing a rigorous peer review system for evaluating digital geoscience education resources under consideration for acceptance into a digital library. The objective is the basis for developing a digital library of the highest quality that will become a trusted resource for Earth science instructors. Our model is NSF-style review panels. Panels were convened in locations having colleges, universities, and labs: Philadelphia, Boston, Austin, St. Petersburg, Seattle, Tucson, and Portland (Maine). The conveners traveled to the sites for the panel meetings. Panelists were reputable geoscience and geoscience education experts. The panelists proved to be uniformly supportive of the process and valued both the experience of serving on the panels and the introduction to resources they could take back to their classroom; thus, the process proved to have a valuable community-building component. The resources reviewed in the experiment, grouped by theme, were provided by the Science Education Resource Center at Carleton College; they are also catalogued in DLESE and NSDL. Panelists wrote reviews that addressed the criteria: 1) scientific accuracy and currency, 2) usability, and 3) pedagogical effectiveness. Additionally, the reviews addressed the questions: 1) Does this resource make an important contribution to Earth system education? 2) Would you recommend this resource to a colleague? and If you recommend major revisions for this resource, would you be willing to review it again? Each review concluded with a recommended action: 1) Accept, 2) Accept with minor revisions, 3) Accept with major revisions, or 4) Reject. Accept with major revisions requires a review by a subset of the panel conducting the original review. Once accepted, a resource enters a reviewed collection, with a specific indicator that it has been through the peer review process. Each panel was invited to single out those resources they considered particularly exemplary, which we refer to as a gold star rating; such resources will be indicated as such in the reviewed collection. Following the panel meetings, the conveners wrote summaries of the panel discussion for each resource; these are transmitted to the creator, along with anonymous versions of the reviews. The panel process proved to be a critical filter for the reviewed resources. Relatively few resources were accepted as is. In most cases, the majority of the resources were either designated as 1) Reject or 2) Accept with major revisions. Resources were most often rejected for their lack of completeness to be used in a classroom or they contained scientific accuracies. The review process modeled provides a basis for building a trusted geoscience education digital library of the highest quality on a less-is-more foundation, as opposed to the prevailing more-is-better philosophy. project.org/isovera/peerreview

Using Scientific Visualizations to Enhance Scientific Thinking In K-12 Geoscience Education

NASA Astrophysics Data System (ADS)

Robeck, E.

2016-12-01

The same scientific visualizations, animations, and images that are powerful tools for geoscientists can serve an important role in K-12 geoscience education by encouraging students to communicate in ways that help them develop habits of thought that are similar to those used by scientists. Resources such as those created by NASA's Scientific Visualization Studio (SVS), which are intended to inform researchers and the public about NASA missions, can be used in classrooms to promote thoughtful, engaged learning. Instructional materials that make use of those visualizations have been developed and are being used in K-12 classrooms in ways that demonstrate the vitality of the geosciences. For example, the Center for Geoscience and Society at the American Geosciences Institute (AGI) helped to develop a publication that outlines an inquiry-based approach to introducing students to the interpretation of scientific visualizations, even when they have had little to no prior experience with such media. To facilitate these uses, the SVS team worked with Center staff and others to adapt the visualizations, primarily by removing most of the labels and annotations. Engaging with these visually compelling resources serves as an invitation for students to ask questions, interpret data, draw conclusions, and make use of other processes that are key components of scientific thought. This presentation will share specific resources for K-12 teaching (all of which are available online, from NASA, and/or from AGI), as well as the instructional principles that they incorporate.

Professional Development Opportunities for Two-Year College Geoscience Faculty: Issues, Opportunities, and Successes

NASA Astrophysics Data System (ADS)

Baer, E. M.; Macdonald, H.; McDaris, J. R.; Granshaw, F. D.; Wenner, J. M.; Hodder, J.; van der Hoeven Kraft, K.; Filson, R. H.; Guertin, L. A.; Wiese, K.

2011-12-01

Two-year colleges (2YCs) play a critical role in geoscience education in the United States. Nearly half of the undergraduate students who take introductory geoscience do so at a 2YC. With awide reach and diverse student populations, 2YCs may be key to producing a well-trained, diverse and sufficiently large geoscience workforce. However, faculty at 2YCs often face many barriers to professional development including lack of financial resources, heavy and inflexible teaching loads, lack of awareness of opportunities, and few professional development resources/events targeted at their needs. As an example, at the 2009 GSA meeting in Portland, fewer than 80 of the 6500 attendees were from community colleges, although this was more than twice the 2YC faculty attendance the previous year. Other issues include the isolation described by many 2YC geoscience faculty who may be the only full time geoscientist on a campus and challenges faced by adjunct faculty who may have even fewer opportunities for professional development and networking with other geoscience faculty. Over the past three years we have convened several workshops and events for 2YC geoscience faculty including technical sessions and a workshop on funding opportunities for 2YC faculty at GSA annual meetings, a field trip and networking event at the fall AGU meeting, a planning workshop that examined the role of 2YCs in geoscience education and in broadening participation in the geosciences, two workshops supporting use of the 'Math You Need, When You Need It' educational materials that included a majority of 2YC faculty, and marine science summer institutes offered by COSEE-Pacific Partnerships for 2YC faculty. Our experience indicates that 2YC faculty desire professional development opportunities when the experience is tailored to the needs and character of their students, programs, and institutions. The content of the professional development opportunity must be useful to 2YC faculty -workshops and materials aimed at K-12 or at faculty teaching geoscience majors tend not to attract 2YC faculty. Conducting a needs assessment and including 2YC faculty in workshop planning helps ensure that the outcomes of professional development opportunities for 2YC faculty are achieved. Financial support for travel seems to be important, although typically it is not necessary to compensate 2YC faculty beyond expenses. 2YC faculty availability varies significantly during the summer as well as during the academic year, so offering multiple opportunities throughout the year and/or virtual events is important. The Geo2YC website at SERC is a resource for geoscience education at two-year colleges and the associated Geo2YC mailing has facilitated the targeted marketing of opportunities for this important group of educators.

Creating an Integrated Community-Wide Effort to Enhance Diversity in the Geosciences

NASA Astrophysics Data System (ADS)

Manduca, C. A.; Weingroff, M.

2001-05-01

Supporting the development and sustenance of a diverse geoscience workforce and improving Earth system education for the full diversity of students are important goals for our community. There are numerous established programs and many new efforts beginning. However, these efforts can become more powerful if dissemination of opportunities, effective practices, and web-based resources enable synergies to develop throughout our community. The Digital Library for Earth System Education (DLESE; www.dlese.org) has developed a working group and a website to support these goals. The DLESE Diversity Working Group provides an open, virtual community for those interested in enhancing diversity in the geosciences. The working group has focused its initial effort on 1) creating a geoscience community engaged in supporting increased diversity that builds on and is integrated with work taking place in other venues; 2) developing a web resource designed to engage and support members of underrepresented groups in learning about the Earth; and 3) assisting in enhancing DLESE collections and services to better support learning experiences of students from underrepresented groups. You are invited to join the working group and participate in these efforts. The DLESE diversity website provides a mechanism for sharing information and resources. Serving as a community database, the website provides a structure in which community members can post announcements of opportunities, information on programs, and links to resources and services. Information currently available on the site includes links to professional society activities; mentoring opportunities; grant, fellowship, employment, and internship opportunities for students and educators; information on teaching students from underrepresented groups; and professional development opportunities of high interest to members of underrepresented groups. These tools provide a starting point for developing a community wide effort to enhance diversity in the geosciences that builds on our collective experiences, knowledge and resources and the work that is taking place in communities around us.

GeoEn -Research on Geo-Energy

NASA Astrophysics Data System (ADS)

Liebscher, A.; Scheck-Wenderoth, M.; GeoEn Research Group

2012-04-01

Axel Liebscher1, Magdalena Scheck-Wenderoth1 and the GeoEn Research Group1, 2,3 1 Helmholtz Centre Potsdam GFZ German Research Centre for Geosciences, Potsdam, Germany 2 University Potsdam, Germany 3 BTU Cottbus, Germany One of the pressing challenges for the 21st century is a secure, sustainable and economical energy supply at simultaneous mitigation of its climate impact. Besides a switch to renewable energy resources, the exploration and exploitation of new, unconventional energy resources will play a major role as will the further use of fossil fuels. With the switch to renewable energies the question of geological energy storage will become an important topic whereas further use of fossil fuels requires strategies like CCS to reduce its negative climate impacts. These different aspects of geo-energy make complementary or competitive demands on the subsurface and its use. It is therefore essential to treat the subsurface as a geo-resource of its own right. So far, geo-resource related research has often focused on specific resource systems, e.g. ore forming systems, hydrocarbon systems or geothermal systems, providing results largely applicable only to the restricted range of physicochemical properties of the respective geo-resource systems. However, with the increasing use of the subsurface as important geo-resource, the different geo-resource systems tend to overlap and interact and also become much more complex due to the additional use or presence of artificial and technical matter, as is the case in geological CO2 storage. On the other hand, the combined use of the subsurface for different purposes may also create synergetic effects. GeoEn is a joint research project explicitly addressing the fundamental questions related to the sustainable and holistic use of the geo-resource subsurface with a special focus on geo-energy. Project partners are the German Research Centre for Geosciences (GFZ), the University of Potsdam (UP) and the Brandenburg University of Technology (BTU). GeoEn research addresses CO2 capture, transport and utilization, CO2 storage, the unconventional energy resource shale gas and geothermal technologies. These four core topics are studied in an integrated approach using the synergy of cross-cutting themes. The latter encompass new exploration and reservoir technologies as well as innovative monitoring methods, both complemented by numerical simulations of the relevant processes including flow dynamics or heat transfer in the subsurface and along the technological process chains. Accordingly, synergies derived from the cross-cutting topics improve both methodological development applicable in equal measure to the utilization of geothermal energy and of shale gas as well as to the use and monitoring of CO2 storage. Complementary, new modelling approaches are developed that allow the simulation of involved processes to predict the occurrence and physical properties of potential reservoirs and the changes that may be induced by their utilization. We present first results with respect to exploration strategies, monitoring technologies and modeling approaches for the pilot storage site for CO2 in Ketzin and the geothermal research platform Groß-Schönebeck, where the respective technologies are tested and monitored.

Simplifying the Reuse and Interoperability of Geoscience Data Sets and Models with Semantic Metadata that is Human-Readable and Machine-actionable

NASA Astrophysics Data System (ADS)

Peckham, S. D.

2017-12-01

Standardized, deep descriptions of digital resources (e.g. data sets, computational models, software tools and publications) make it possible to develop user-friendly software systems that assist scientists with the discovery and appropriate use of these resources. Semantic metadata makes it possible for machines to take actions on behalf of humans, such as automatically identifying the resources needed to solve a given problem, retrieving them and then automatically connecting them (despite their heterogeneity) into a functioning workflow. Standardized model metadata also helps model users to understand the important details that underpin computational models and to compare the capabilities of different models. These details include simplifying assumptions on the physics, governing equations and the numerical methods used to solve them, discretization of space (the grid) and time (the time-stepping scheme), state variables (input or output), model configuration parameters. This kind of metadata provides a "deep description" of a computational model that goes well beyond other types of metadata (e.g. author, purpose, scientific domain, programming language, digital rights, provenance, execution) and captures the science that underpins a model. A carefully constructed, unambiguous and rules-based schema to address this problem, called the Geoscience Standard Names ontology will be presented that utilizes Semantic Web best practices and technologies. It has also been designed to work across science domains and to be readable by both humans and machines.

Integrating Place-based Science and Data into Hydrology and Geoscience Education Using the CUAHSI Water Data Center Resources

NASA Astrophysics Data System (ADS)

Arrigo, J. S.; Dalbotten, D. M.; Hooper, R. P.; Pollak, J.; Geosling, E.

2014-12-01

"All water is local." For geoscientist researchers and educators, this simple statement underlies potentially powerful ways to engage students around hydrologic and engineering concepts. Education research has given us strong insight into how students learn. Place-based education gives students a personal and geographical context to connect concepts and processes to their everyday lives. Data-driven exercises build inquiry and critical thinking skills. With the ubiquity of water, the critical roles it plays in earth systems, and its influence on ecosystems, climate, geologic processes, economies, and human health, integrating water data and place-based exercises into the classroom is an excellent opportunity to enhance student learning and stimulate interest in the geosciences. THE CUAHSI Water Data Center (WDC), established in 2013, is the culmination of a decade of work to adapt modern web services technology to work on time-series data (such as a gage record or water-quality series), the most common water data type. It provides unprecedented consolidated access to water quantity and quality data across the US (and increasingly across the world). This allows educators to craft learning exercises around key concepts and locations, from rote problem sets to more exploratory investigations. The web services technology used address key limitations - such as difficulty in discovering data, co-locating data, and download options and access- that have been identified as barriers to integrating real data in classroom exercises. This presentation discusses key aspects of the system, provides example exercises, and discusses how we seek to engage the community to effectively chart a path forward for further development of both the technological and education resources.

A Model Collaborative Platform for Geoscience Education

NASA Astrophysics Data System (ADS)

Fox, S.; Manduca, C. A.; Iverson, E. A.

2012-12-01

Over the last decade SERC at Carleton College has developed a collaborative platform for geoscience education that has served dozens of projects, thousands of community authors and millions of visitors. The platform combines a custom technical infrastructure: the SERC Content Management system (CMS), and a set of strategies for building web-resources that can be disseminated through a project site, reused by other projects (with attribution) or accessed via an integrated geoscience education resource drawing from all projects using the platform. The core tools of the CMS support geoscience education projects in building project-specific websites. Each project uses the CMS to engage their specific community in collecting, authoring and disseminating the materials of interest to them. At the same time the use of a shared central infrastructure allows cross-fertilization among these project websites. Projects are encouraged to use common templates and common controlled vocabularies for organizing and displaying their resources. This standardization is then leveraged through cross-project search indexing which allow projects to easily incorporate materials from other projects within their own collection in ways that are relevant and automated. A number of tools are also in place to help visitors move among project websites based on their personal interests. Related links help visitors discover content related topically to their current location that is in a 'separate' project. A 'best bets' feature in search helps guide visitors to pages that are good starting places to explore resources on a given topic across the entire range of hosted projects. In many cases these are 'site guide' pages created specifically to promote a cross-project view of the available resources. In addition to supporting the cross-project exploration of specific themes the CMS also allows visitors to view the combined suite of resources authored by any particular community member. Automatically generated author profiles highlight the contributions an individual has made through any of the projects with an option for customization by the author. An overarching portal site provides a unified view of resources within this diverse set of geoscience education projects. The SERC CMS provides a common platform upon which individual projects can build their own identities, while allowing cross-project pollination and synergies to be realized without significant extra investment by each project. This is a sustainable model for a collaborative platform that takes advantage of the energy and resources of individual projects to advance larger community goals.

Geoscience Education Research: A Brief History, Context and Opportunities

NASA Astrophysics Data System (ADS)

Mogk, D. W.; Manduca, C. A.; Kastens, K. A.

2011-12-01

DBER combines knowledge of teaching and learning with deep knowledge of discipline-specific science content. It describes the discipline-specific difficulties learners face and the specialized intellectual and instructional resources that can facilitate student understanding (NRC, 2011). In the geosciences, content knowledge derives from all the "spheres, the complex interactions of components of the Earth system, applications of first principles from allied sciences, an understanding of "deep time", and approaches that emphasize the interpretive and historical nature of geoscience. Insights gained from the theory and practice of the cognitive and learning sciences that demonstrate how people learn, as well as research on learning from other STEM disciplines, have helped inform the development of geoscience curricular initiatives. The Earth Science Curriculum Project (1963) was strongly influenced by Piaget and emphasized hands-on, experiential learning. Recognizing that education research was thriving in related STEM disciplines a NSF report (NSF 97-171) recommended "... that GEO and EHR both support research in geoscience education, helping geoscientists to work with colleagues in fields such as educational and cognitive psychology, in order to facilitate development of a new generation of geoscience educators." An NSF sponsored workshop, Bringing Research on Learning to the Geosciences (2002) brought together geoscience educators and cognitive scientists to explore areas of mutual interest, and identified a research agenda that included study of spatial learning, temporal learning, learning about complex systems, use of visualizations in geoscience learning, characterization of expert learning, and learning environments. Subsequent events have focused on building new communities of scholars, such as the On the Cutting Edge faculty professional development workshops, extensive collections of online resources, and networks of scholars that have addressed teaching with visualizations, the affective domain, observing and assessing student learning, metacognition, and understanding complex systems. Geoscience education research is a growing and thriving field of scholarship that includes new PhD programs in geocognition (e.g. Michigan State Univ., Purdue Univ., Arizona State Univ., North Carolina State Univ.), and numerous collaborative research consortia (e.g. Synthesis of Research on Learning in the Geosciences; Spatial Intelligence and Learning Center, Geoscience Affective Research Network). The results of geoscience education research are presently being incorporated into the geoscience curriculum through teaching activities and textbooks. These many contributions reveal the need for sustained research on related topics: assessments of student learning, learning environments (lab and field), "what works" for different learning audiences, learning in upper division disciplinary courses, the nature of geoscience expertise. The National Research Council is currently reviewing the Status, Contributions, and Future Direction of Discipline-Based Education Research (DBER), see: http://www7.nationalacademies.org/bose/DBER_Homepage.html

Constructing a Cross-Domain Resource Inventory: Key Components and Results of the EarthCube CINERGI Project.

NASA Astrophysics Data System (ADS)

Zaslavsky, I.; Richard, S. M.; Malik, T.; Hsu, L.; Gupta, A.; Grethe, J. S.; Valentine, D. W., Jr.; Lehnert, K. A.; Bermudez, L. E.; Ozyurt, I. B.; Whitenack, T.; Schachne, A.; Giliarini, A.

2015-12-01

While many geoscience-related repositories and data discovery portals exist, finding information about available resources remains a pervasive problem, especially when searching across multiple domains and catalogs. Inconsistent and incomplete metadata descriptions, disparate access protocols and semantic differences across domains, and troves of unstructured or poorly structured information which is hard to discover and use are major hindrances toward discovery, while metadata compilation and curation remain manual and time-consuming. We report on methodology, main results and lessons learned from an ongoing effort to develop a geoscience-wide catalog of information resources, with consistent metadata descriptions, traceable provenance, and automated metadata enhancement. Developing such a catalog is the central goal of CINERGI (Community Inventory of EarthCube Resources for Geoscience Interoperability), an EarthCube building block project (earthcube.org/group/cinergi). The key novel technical contributions of the projects include: a) development of a metadata enhancement pipeline and a set of document enhancers to automatically improve various aspects of metadata descriptions, including keyword assignment and definition of spatial extents; b) Community Resource Viewers: online applications for crowdsourcing community resource registry development, curation and search, and channeling metadata to the unified CINERGI inventory, c) metadata provenance, validation and annotation services, d) user interfaces for advanced resource discovery; and e) geoscience-wide ontology and machine learning to support automated semantic tagging and faceted search across domains. We demonstrate these CINERGI components in three types of user scenarios: (1) improving existing metadata descriptions maintained by government and academic data facilities, (2) supporting work of several EarthCube Research Coordination Network projects in assembling information resources for their domains, and (3) enhancing the inventory and the underlying ontology to address several complicated data discovery use cases in hydrology, geochemistry, sedimentology, and critical zone science. Support from the US National Science Foundation under award ICER-1343816 is gratefully acknowledged.

Assessing Quantitative Learning With The Math You Need When You Need It

NASA Astrophysics Data System (ADS)

Wenner, J. M.; Baer, E. M.; Burn, H.

2008-12-01

We present new data from a pilot project using the The Math You Need, When You Need It (TMYN) web resources in conjunction with several introductory geoscience courses. TMYN is a series of NSF-supported, NAGT-sponsored, web-based modular resources designed to help students learn (or relearn) mathematical skills essential for success in introductory geoscience courses. TMYN presents mathematical topics that are relevant to introductory geoscience based on a survey of more than 75 geoscience faculty members. To date, modules include unit conversions, many aspects of graphing, density calculations, rearranging equations and other simple mathematical concepts commonly used in the geosciences. The modular nature of the resources make it simple to select the units that are appropriate for a given course. In the fall of 2008, nine TMYN modules were tested in three courses taught at Highline Community College (Geology 101) and University of Wisconsin Oshkosh (Physical and Environmental Geology). Over 300 students participated in the study by taking pre- and post-tests and completing modules relevant to their course. Feedback about the use of these modules has been mixed. Initial results confirm anecdotal evidence that students initially have difficulty applying mathematical concepts to geologic problems. Furthermore, pre- test results indicate that, although instructors assume that students can perform simple mathematical manipulations, many students arrive in courses without the skills to apply mathematical concepts in problem solving situations. TMYN resources effectively provide support for learning quantitative problem solving and a mechanism for students to engage in self-teaching. Although we have seen mixed results due to a range of instructor engagement with the material, TMYN can have significant effect on students who are math phobic or "can't do math" because they can work at their own pace to overcome affective obstacles such as fear and dislike of mathematics. TMYN is most effective when instructors make explicit connections between material in the modules and course content. Instructors who participated in the study in Fall 2008 reacted positively to the use of TMYN in introductory geoscience courses because the resources require minimal class and prep time. Furthermore, when instructors can hold students responsible for the quantitative concepts covered with TMYN, they feel more comfortable including quantitative information without significant loss of geologic content.

Building and Sustaining International Scientific Partnerships Through Data Sharing

NASA Astrophysics Data System (ADS)

Ramamurthy, M. K.; Yoksas, T.

2008-05-01

Understanding global environmental processes and their regional linkages has heightened the importance of strong international scientific partnerships. At the same time, the Internet and its myriad manifestations, along with innovative web services, have amply demonstrated the compounding benefits of cyberinfrastructure and the power of networked communities. The increased globalization of science, especially in solving interdisciplinary Earth system science problems, requires that science be conducted collaboratively by distributed teams of investigators, often involving sharing of knowledge and resources like community models and other tools. The climate system, for example, is far too complex a puzzle to be unraveled by individual investigators or nations. Its understanding requires finding, collecting, integrating, and assimilating data from observations and model simulations from diverse fields and across traditional disciplinary boundaries. For the past two decades, the NSF-sponsored Unidata Program Center has been providing the data services, tools, and cyberinfrastructure leadership that advance Earth system science education and research, and enabled opportunities for broad participation. Beginning as a collection of US-based, mostly atmospheric science departments, the Unidata community now transcends international boundaries and geoscience disciplines. Today, Unidata technologies are used in many countries on all continents in research, education and operational settings, and in many international projects (e.g., IPCC assessments, International Polar Year, and THORPEX). The program places high value on the transformational changes enabled by such international scientific partnerships and continually provides opportunities to share knowledge, data, tools and other resources to advance geoscience research and education. This talk will provide an overview of Unidata's ongoing efforts to foster to international scientific partnerships toward building a globally-engaged community of educators and researchers in the geosciences. The presentation will discuss how developments in Earth and Space Science Informatics are enabling new approaches to solving geoscientific problems. The presentation will also describe how Unidata resources are being leveraged by broader initiatives in UCAR and elsewhere.

A Geoscience Workforce Model for Non-Geoscience and Non-Traditional STEM Students

NASA Astrophysics Data System (ADS)

Liou-Mark, J.; Blake, R.; Norouzi, H.; Vladutescu, D. V.; Yuen-Lau, L.

2016-12-01

The Summit on the Future of Geoscience Undergraduate Education has recently identified key professional skills, competencies, and conceptual understanding necessary in the development of undergraduate geoscience students (American Geosciences Institute, 2015). Through a comprehensive study involving a diverse range of the geoscience academic and employer community, the following professional scientist skills were rated highly important: 1) critical thinking/problem solving skills; 2) effective communication; 3) ability to access and integrate information; 4) strong quantitative skills; and 5) ability to work in interdisciplinary/cross cultural teams. Based on the findings of the study above, the New York City College of Technology (City Tech) has created a one-year intensive training program that focusses on the development of technical and non-technical geoscience skills for non-geoscience, non-traditional STEM students. Although City Tech does not offer geoscience degrees, the primary goal of the program is to create an unconventional pathway for under-represented minority STEM students to enter, participate, and compete in the geoscience workforce. The selected cohort of STEM students engage in year-round activities that include a geoscience course, enrichment training workshops, networking sessions, leadership development, research experiences, and summer internships at federal, local, and private geoscience facilities. These carefully designed programmatic elements provide both the geoscience knowledge and the non-technical professional skills that are essential for the geoscience workforce. Moreover, by executing this alternate, robust geoscience workforce model that attracts and prepares underrepresented minorities for geoscience careers, this unique pathway opens another corridor that helps to ameliorate the dire plight of the geoscience workforce shortage. This project is supported by NSF IUSE GEOPATH Grant # 1540721.

Promoting the Geosciences for Minority Students in the Urban Coastal Environment of New York City

NASA Astrophysics Data System (ADS)

Liou-Mark, J.; Blake, R.

2013-12-01

The 'Creating and Sustaining Diversity in the Geo-Sciences among Students and Teachers in the Urban Coastal Environment of New York City' project was awarded to New York City College of Technology (City Tech) by the National Science Foundation to promote the geosciences for students in middle and high schools and for undergraduates, especially for those who are underrepresented minorities in STEM. For the undergraduate students at City Tech, this project: 1) created and introduced geoscience knowledge and opportunities to its diverse undergraduate student population where geoscience is not currently taught at City Tech; and 2) created geoscience articulation agreements. For the middle and high schools, this project: 1) provided inquiry-oriented geoscience experiences (pedagogical and research) for students; 2) provided standards-based professional development (pedagogical and research) in Earth Science for teachers; 3) developed teachers' inquiry-oriented instructional techniques through the GLOBE program; 4) increased teacher content knowledge and confidence in the geosciences; 5) engaged and intrigued students in the application of geoscience activities in a virtual environment; 6) provided students and teachers exposure in the geosciences through trip visitations and seminars; and 7) created community-based geoscience outreach activities. Results from this program have shown significant increases in the students (grades 6-16) understanding, participation, appreciation, and awareness of the geosciences. Geoscience modules have been created and new geosciences courses have been offered. Additionally, students and teachers were engaged in state-of-the-art geoscience research projects, and they were involved in many geoscience events and initiatives. In summary, the activities combined geoscience research experiences with a robust learning community that have produced holistic and engaging stimuli for the scientific and academic growth and development of grades 6 - 12 student and teacher participants and undergraduates. (This program is supported by NSF OEDG grant #1108281.)

The YES Network: IYPE's Motto 'Earth Sciences for Society

NASA Astrophysics Data System (ADS)

Gonzales, Leila; Keane, Christopher

2010-05-01

The YES Network is an international association of early-career geoscientists who are primarily under the age of 35 years and are currently engaged in the geosciences in organizations from across the world. The YES Network was formed as a result of the International Year of Planet Earth in 2007. The YES Network aims to establish an interdisciplinary global network of individuals committed to solving these challenges, and furthering the IYPE motto of "Earth Sciences for Society". In 2009, in collaboration with the IYPE and under the patronage of UNESCO, the YES Network organized its first international Congress at the China University of Geosciences in Beijing, China. The Congress focused on climate, environmental and geoscience challenges facing today's society, as well as career and academic pathway challenges faced by early-career geoscientists. More than 300 young geoscientists from across the world attended the conference to present their research and participate in the oral, poster, and roundtable symposia. The roundtable symposia engaged senior and early-career geoscientists via presentations, panel discussions, and working group sessions. These symposia were broadcast as ‘live' webinars to increase international participation. As a result, 41 "virtual" participants from 10 countries and 16 "virtual" speakers from 5 countries were able to participate in these discussions. Since October, the YES Network has continued to expand its membership and develop more projects aligned with the "Earth Sciences for Society" motto. The YES Network is continuing to develop its website and social media networks to increase communication between YES Network members on local, regional and international scales, and it is developing resources to aid early-career geoscientists with opportunities for professional development, international collaboration, and involvement in outreach activities. Members of the YES Network are actively forming connections between the YES Network and the major international geoscience associations. The YES Network presented talks about the development of YES Network and about the October meeting at the American Geophysical Union's Fall Meeting. At the EGU 2010 meeting, the YES Network has organized symposia on ocean acidification and the "OneGeology" initiative. In 2011, the YES Network will be organizing poster, oral and roundtable sessions at the CAG23 meeting in Johannesburg. In 2012, the second international YES Congress will be held in conjunction with the 34th IGC. Other YES Network projects currently underway include a survey of the international community of young and early-career geoscientists pertaining to decision points in their academic and career paths, and a research project pertaining to mineral resources in Africa. The YES Network is able to function as a dynamic association because of several factors. It is comprised of young geoscientists who use technology to communicate and collaborate in ways that were not available to previous generations. Second, the YES Network has built its mission around the IYPE motto "Earth Sciences for Society.". The YES Network, via its use of web-based technologies, is able to progressively influence society's focus on geoscience issues because of the YES Network's ability to easily and effectively collaborate internationally on projects, build linkages within the international geoscience community, and create outreach activist that inform the general public.

Roadblocks Hampering the Professional Development of Geoscientists in AFRICA.- a Case Study from the Ghanaian Perspective

NASA Astrophysics Data System (ADS)

Kabore, A.

2010-12-01

Ghana, like many African countries is in a strategic position to promote the development of early-career geoscientist because of the huge potential in terms of geological resources, huge number of interested students, and a number of institutions for training geoscientists. Ghana is often described as the gateway to Africa. As a result, situations that hamper the development of early career geoscientists in Ghana are likely to be replicated in many African countries. Over the last few decades, several institutions have been created to develop the technical-geoscientific expertise, and to deal with the disparity that exists between the amount of work that needs to be done in the geosciences and the small number of geoscientists working in the profession. There are more than four universities in Ghana that offer the study of geosciences. Available statistics indicate that the number of students enrolled in these institutions has seen a distinct increase over the last few decades. However, a significant percentage of the graduates from these institutions do not work in their core profession or even in closely-aligned disciplines. Unfortunately, the problem of a small national geosciences workforce is more pronounced today than it was over the last few decades. This problem is not a result of the lack of trained geoscientists, but rather a combination of several factors which may be socio-economic, cultural, passion, lack of mentorship etc. This presentation will focus on the broad challenges and institutional difficulties that geosciences graduates and early career professional face in Ghana and in Africa. Several recommendations will be proposed to address these problems and foster the establishment of professional development resources to boost the flow of geosciences graduates into the profession. These proposed resources will enable graduates to develop not only the skills and experience needed in the profession, but also the passion to become future leaders within the geosciences community.

Teaching GeoEthics Across the Geoscience Curriculum

NASA Astrophysics Data System (ADS)

Mogk, D. W.; Geissman, J. W.; Kieffer, S. W.; Reidy, M.; Taylor, S.; Vallero, D. A.; Bruckner, M. Z.

2014-12-01

Ethics education is an increasingly important component of the pre-professional training of geoscientists. Funding agencies (NSF) require training of graduate students in the responsible conduct of research, employers are increasingly expecting their workers to have basic training in ethics, and the public demands that scientists abide by the highest standards of ethical conduct. Yet, few faculty have the requisite training to effectively teach about ethics in their classes, or even informally in mentoring their research students. To address this need, an NSF-funded workshop was convened to explore how ethics education can be incorporated into the geoscience curriculum. Workshop goals included: examining where and how geoethics topics can be taught from introductory courses for non-majors to modules embedded in "core" geoscience majors courses or dedicated courses in geoethics; sharing best pedagogic practices for "what works" in ethics education; developing a geoethics curriculum framework; creating a collection of online instructional resources, case studies, and related materials; applying lessons learned about ethics education from sister disciplines (biology, engineering, philosophy); and considering ways that geoethics instruction can contribute to public scientific literacy. Four major themes were explored in detail: (1) GeoEthics and self: examining the internal attributes of a geoscientist that establish the ethical values required to successfully prepare for and contribute to a career in the geosciences; (2) GeoEthics and the geoscience profession: identifying ethical standards expected of geoscientists if they are to contribute responsibly to the community of practice; (3) GeoEthics and society: exploring geoscientists' responsibilities to effectively and responsibly communicate the results of geoscience research to inform society about issues ranging from geohazards to natural resource utilization in order to protect public health, safety, and economic security; (4) GeoEthics and Earth: explicating geoscientists' responsibilities to provide stewardship towards of the Earth based on their knowledge of Earth's composition, architecture, history, dynamic processes, and complex systems. Workshop resources can be accessed at serc.carleton.edu/geoethics/

System design and implementation of digital-image processing using computational grids

NASA Astrophysics Data System (ADS)

Shen, Zhanfeng; Luo, Jiancheng; Zhou, Chenghu; Huang, Guangyu; Ma, Weifeng; Ming, Dongping

2005-06-01

As a special type of digital image, remotely sensed images are playing increasingly important roles in our daily lives. Because of the enormous amounts of data involved, and the difficulties of data processing and transfer, an important issue for current computer and geo-science experts is developing internet technology to implement rapid remotely sensed image processing. Computational grids are able to solve this problem effectively. These networks of computer workstations enable the sharing of data and resources, and are used by computer experts to solve imbalances of network resources and lopsided usage. In China, computational grids combined with spatial-information-processing technology have formed a new technology: namely, spatial-information grids. In the field of remotely sensed images, spatial-information grids work more effectively for network computing, data processing, resource sharing, task cooperation and so on. This paper focuses mainly on the application of computational grids to digital-image processing. Firstly, we describe the architecture of digital-image processing on the basis of computational grids, its implementation is then discussed in detail with respect to the technology of middleware. The whole network-based intelligent image-processing system is evaluated on the basis of the experimental analysis of remotely sensed image-processing tasks; the results confirm the feasibility of the application of computational grids to digital-image processing.

DAsHER CD: Developing a Data-Oriented Human-Centric Enterprise Architecture for EarthCube

NASA Astrophysics Data System (ADS)

Yang, C. P.; Yu, M.; Sun, M.; Qin, H.; Robinson, E.

2015-12-01

One of the biggest challenges that face Earth scientists is the resource discovery, access, and sharing in a desired fashion. EarthCube is targeted to enable geoscientists to address the challenges by fostering community-governed efforts that develop a common cyberinfrastructure for the purpose of collecting, accessing, analyzing, sharing and visualizing all forms of data and related resources, through the use of advanced technological and computational capabilities. Here we design an Enterprise Architecture (EA) for EarthCube to facilitate the knowledge management, communication and human collaboration in pursuit of the unprecedented data sharing across the geosciences. The design results will provide EarthCube a reference framework for developing geoscience cyberinfrastructure collaborated by different stakeholders, and identifying topics which should invoke high interest in the community. The development of this EarthCube EA framework leverages popular frameworks, such as Zachman, Gartner, DoDAF, and FEAF. The science driver of this design is the needs from EarthCube community, including the analyzed user requirements from EarthCube End User Workshop reports and EarthCube working group roadmaps, and feedbacks or comments from scientists obtained by organizing workshops. The final product of this Enterprise Architecture is a four-volume reference document: 1) Volume one is this document and comprises an executive summary of the EarthCube architecture, serving as an overview in the initial phases of architecture development; 2) Volume two is the major body of the design product. It outlines all the architectural design components or viewpoints; 3) Volume three provides taxonomy of the EarthCube enterprise augmented with semantics relations; 4) Volume four describes an example of utilizing this architecture for a geoscience project.

New Collaborative Strategies for Bringing the Geosciences to Students, Teachers, and the Public: Progress and Opportunities from the National Earth Science Teachers Association and Windows to the Universe

NASA Astrophysics Data System (ADS)

Johnson, R. M.; Herrold, A.; Holzer, M. A.; Passow, M. J.

2010-12-01

The geoscience research and education community is interested in developing scalable and effective user-friendly strategies for reaching the public, students and educators with information about the Earth and space sciences. Based on experience developed over the past decade with education and outreach programs seeking to reach these populations, there is a growing consensus that this will be best achieved through collaboration, leveraging the resources and networks already in existence. While it is clear that gifted researchers and developers can create wonderful online educational resources, many programs have been stymied by the difficulty of attracting an audience to these resources. The National Earth Science Teachers Association (NESTA) has undertaken an exciting new project, with support from the William and Flora Hewlett Foundation, that provides a new platform for the geoscience education and research community to share their research, resources, programs, products and services with a wider audience. In April 2010, the Windows to the Universe project (http://windows2universe.org) moved from the University Corporation for Atmospheric Research to NESTA. Windows to the Universe, which started in 1995 at the University of Michigan, is one of the most popular Earth and space science education websites globally, with over 16 million visits annually. The objective of this move is to develop a suite of new opportunities and capabilities on the website that will allow it become a sustainable education and outreach platform for the geoscience research and education community hosting open educational resources. This presentation will provide an update on our progress, highlighting our new strategies, synergies with community needs, and opportunities for collaboration.

Summaries of FY 1993 geosciences research

DOE Office of Scientific and Technical Information (OSTI.GOV)

Not Available

1993-12-01

The Department of Energy supports research in the geosciences in order to provide a sound foundation of fundamental knowledge in those areas of the geosciences that are germane to the DOE`s many missions. The Geosciences Research Program is supported by the Office of Energy Research. The participants in this program include DOE laboratories, academic institutions, and other governmental agencies. These activities are formalized by a contract or grant between the DOE and the organization performing the work, providing funds for salaries, equipment, research materials, and overhead. The summaries in this document, prepared by the investigators, describe the scope of themore » individual programs. The Geosciences Research Program includes research in geophysics, geochemistry, resource evaluation, solar-terrestrial interactions, and their subdivisions including earth dynamics, properties of earth materials, rock mechanics, underground imaging, rock-fluid interactions, continental scientific drilling, geochemical transport, solar-atmospheric physics, and modeling, with emphasis on the interdisciplinary areas.« less

Highlighting Successful Strategies for Engaging Minority Students in the Geosciences

NASA Astrophysics Data System (ADS)

Liou-Mark, J.; Blake, R.; Norouzi, H.; Vladutescu, D. V.; Yuen-Lau, L.

2017-12-01

Igniting interest and creativity in students for the geosciences oftentimes require innovation, bold `outside-the-box' thinking, and perseverance, particularly for minority students for whom the preparation for the discipline and its lucrative pathways to the geoscience workforce are regrettably unfamiliar and woefully inadequate. The enrollment, retention, participation, and graduation rates of minority students in STEM generally and in the geosciences particularly remain dismally low. However, a coupled, strategic geoscience model initiative at the New York City College of Technology (City Tech) of the City University of New York has been making steady in-roads of progress, and it offers practical solutions to improve minority student engagement in the geosciences. Aided by funding from the National Science Foundation (NSF), two geoscience-centric programs were created from NSF REU and NSF IUSE grants, and these programs have been successfully implemented and administered at City Tech. This presentation shares the hybrid geoscience research initiatives, the multi-tiered mentoring structures, the transformative geoscience workforce preparation, and a plethora of other vital bastions of support that made the overall program successful. Minority undergraduate scholars of the program have either moved on to graduate school, to the geoscience workforce, or they persist with greater levels of success in their STEM disciplines.

Examining the Real Merits of the Virtual Microscope

NASA Astrophysics Data System (ADS)

Hennessy, Ronan; Meere, Pat; Ho, Timsie; Menuge, Julian; Tyrrell, Shane; Kamber, Balz; Higgs, Bettie; Kelley, Simon

2017-04-01

The Geoscience e-Laboratory (GeoLAB) project is a cooperative digital petrological microscopy technology enhanced learning (TEL) resource development project involving the four main university geoscience teaching centres in Ireland. Collaborating with the Open University (UK), a new digital library of petrographic thin sections has been added to the Virtual Microscope for Earth Sciences (VMfES) online repository. The collection was compiled with a view to introducing high-quality samples to teaching programmes in a manner that hitherto was limited by sample and microscope availability and cost and the temporal limits of laboratory access. The project has proceeded to explore the pedagogical implications of using the Virtual Microscope in teaching programmes. Online assessments and self-guided exercises developed using applications such as Google Forms have been introduced into programmes at each centre, and complimented by tutorial and interactive videos designed to support self-guided learning. The GeoLab project is reporting on the pedagogical implications of providing students with unimpeded access to high-quality petrographic learning resources during the term of semester and in advance of student assessments. Additionally, the project is collating data on the perceptions of both teachers and learners to using online learning media in mineralogy and petrology programmes, and if there are benefits therein to the more traditional styles of petrology and microscopy teaching and learning.

Due Diligence for Students - Geoscience Skills and Demographic Data for Career Planning

NASA Astrophysics Data System (ADS)

Keane, C. M.

2001-05-01

A major focus of the American Geological Institute's Human Resources program has been providing demographic and employment data so that students and mentors can better understand the dynamics of a career in the geosciences. AGI has a long history of collecting these data for the geoscience community, including 46 years of geoscience enrollments, periodic comprehensive surveys of employment in the discipline, and working closely with other organizations that collect these data. AGI has launched a new suite of surveys to examine the skills desired by employers and the skills provided through a geoscience education. Historical demographic and enrollment data allow a number of the major trends to be examined. These trends include the dominance of industry as employer in the geosciences and how the cyclicity of geoscience employment has become more complex with the development of the environmental sector over the last 30 years. Additionally, demographics are changing rapidly, with a geoscience workforce that is changing rapidly in age, gender, and background. The discipline may also be facing a change in the nature of geoscience employment, with chronic shortages of skilled geoscientists, but will job opportunities actually increase. This may not be as paradoxical as it appears. The geoindustries are attempting to adjust their strategies to dampen business cycles, which then may lead to more stable employment levels for geoscientists, but they are also broadening their vision of who can become competent geoscientists.

Geoscience Digital Data Resource and Repository Service

NASA Astrophysics Data System (ADS)

Mayernik, M. S.; Schuster, D.; Hou, C. Y.

2017-12-01

The open availability and wide accessibility of digital data sets is becoming the norm for geoscience research. The National Science Foundation (NSF) instituted a data management planning requirement in 2011, and many scientific publishers, including the American Geophysical Union and the American Meteorological Society, have recently implemented data archiving and citation policies. Many disciplinary data facilities exist around the community to provide a high level of technical support and expertise for archiving data of particular kinds, or for particular projects. However, a significant number of geoscience research projects do not have the same level of data facility support due to a combination of several factors, including the research project's size, funding limitations, or topic scope that does not have a clear facility match. These projects typically manage data on an ad hoc basis without limited long-term management and preservation procedures. The NSF is supporting a workshop to be held in Summer of 2018 to develop requirements and expectations for a Geoscience Digital Data Resource and Repository Service (GeoDaRRS). The vision for the prospective GeoDaRRS is to complement existing NSF-funded data facilities by providing: 1) data management planning support resources for the general community, and 2) repository services for researchers who have data that do not fit in any existing repository. Functionally, the GeoDaRRS would support NSF-funded researchers in meeting data archiving requirements set by the NSF and publishers for geosciences, thereby ensuring the availability of digital data for use and reuse in scientific research going forward. This presentation will engage the AGU community in discussion about the needs for a new digital data repository service, specifically to inform the forthcoming GeoDaRRS workshop.

Geoethics in communication of science: the relationship between media and geoscientists

NASA Astrophysics Data System (ADS)

Foresta Martin, Franco; Peppoloni, Silvia

2015-04-01

In the urgency to reconsider the relationship between humankind and planet Earth, in the light of the issues of a sustainable economic and technological development, the defence against natural risks and climate change, the themes addressed by Geoethics are becoming central to the scientific debate. A growing number of scientists begins to consider this discipline as an effective tool to increase, in the scientific community and society as a whole, the awareness of local and global environmental problems that humanity is facing. Geoethics deals with the ethical, social and cultural aspects related to geosciences. It was born with the goal of orienting humankind toward a balanced relationship with the planet and providing references and guidelines to find socio-economic solutions compatible both with the respect for the environment and the protection of nature and land. Geoethics addresses fundamental issues such as the exploitation of geo-resources, the management of natural hazards, the defence of the geoheritage as a common value to be protected and enhanced. But above all geoethics aims at raising in the community of geoscientists the awareness of their responsibilities in conducting the scientific and professional activity. In order to extend this awareness to the whole civil society and also to foster the recognition of the usefulness of geosciences in daily life, it is important to develop a proper communication of the geological knowledge, that is capable to contribute substantially to the construction of the social knowledge of human communities. But nowadays what is the role played by geosciences in the scientific mass culture? Are geosciences part of the collective cultural heritage? Do the publishing world and media in general offer an adequate space to geosciences? Through the analysis of case studies, the authors will highlight the critical features of the relationship between geoscientists and the media system, their different languages, times and perspectives that characterize the geological community and the media world, as well as the most common mistakes made in the communication of geosciences. And as far as the authors are concerned, they will try to suggest some actions, useful to make more functional the relationship between these two separate fields, with the goal of bringing citizens closer to geosciences and increasing the awareness of the individual and collective responsibility towards the planet Earth.

Achieving Broader Impacts Through Partnering in a Digital World

NASA Astrophysics Data System (ADS)

Mogk, D. W.; Manduca, C. A.

2004-12-01

The NSF Broader Impacts review criterion has many possible dimensions: advance discovery and understanding while promoting teaching, training, and learning; broaden participation of under-represented groups; enhance infrastructure for research and education; broad dissemination to enhance scientific and technological understanding; and benefits to society (NSF OPP Advisory Committee). To effectively achieve and demonstrate broader impacts of a research project, it is essential to form meaningful partnerships among many stakeholders: scientists (i.e. content specialists) teachers/faculty, creators of educational resources, students, journalists, policy makers, institutions (e.g. schools, colleges and universities; museums, aquariums, parks), agencies (local, state and federal), and professional societies. Such partnerships are readily supported through digital information technologies and communication networks. The Science Education Resource Center (http://serc.carleton.edu) provides a number of on-line programs that are available for you to participate and contribute in a variety of E&O activities. Exemplars are in development to demonstrate effective ways to integrate research and education. The Using Data in the Classroom portal disseminates data sources, tools, activities and examples. The On the Cutting Edge professional development program will convene a workshop in July 2005 on "Teaching About the Ocean System Using New Research Techniques: Data, Models and Visualizations". The Microbial Life Education Resources digital library is in development and will focus on life in extreme environments this year, and life in the ocean system will be our emphasis in the second year. There is a registry of geochemical analytical instruments to help students and faculty gain access to instrumentation, and geophysical and geospatial analysis facilities will be added in the near future. There are also a wide range of pedagogical resources available to support E&O projects including Research on Learning; Developing Effective On-Line Educational Resources in the Geosciences; Teaching Geoscience with Visualizations: Using Images, Animations, and Models Effectively; and Tips on Assessment, Dissemination, and Partnering. Working group listservs and web-authoring services are available to support collaborations. We invite you to contribute to these collections and services to meet your broader impact goals.

Effectiveness of Geosciences Exploration Summer Program (GeoX) for increasing awareness and Broadening Participation in the Geosciences

NASA Astrophysics Data System (ADS)

Garcia, S. J.; Houser, C.

2013-12-01

Summer research experiences are an increasingly popular means to increase awareness of and develop interest in the Geosciences and other STEM (Science, Technology, Engineering and Math) programs. Here we describe and report the preliminary results of a new one-week program at Texas A&M University to introduce first generation, women, and underrepresented high school students to opportunities and careers in the Geosciences. Short-term indicators in the form of pre- and post-program surveys of participants and their parents suggest that there is an increase in participant understanding of geosciences and interest in pursuing a degree in the geosciences. At the start of the program, the participants and their parents had relatively limited knowledge of the geosciences and very few had a friend or acquaintance employed in the geosciences. Post-survey results suggest that the students had an improved and nuanced understanding of the geosciences and the career opportunities within the field. A survey of the parents several months after the program had ended suggests that the participants had effectively communicated their newfound understanding and that the parents now recognized the geosciences as a potentially rewarding career. With the support of their parents 42% of the participants are planning to pursue an undergraduate degree in the geosciences compared to 62% of participants who were planning to pursue a geosciences degree before the program. It is concluded that future offerings of this and similar programs should also engage the parents to ensure that the geosciences are recognized as a potential academic and career path.

Summaries of FY 1994 geosciences research

DOE Office of Scientific and Technical Information (OSTI.GOV)

Not Available

1994-12-01

The Geosciences Research Program is directed by the Department of Energy`s (DOE`s) Office of Energy Research (OER) through its Office of Basic Energy Sciences (OBES). Activities in the Geosciences Research Program are directed toward the long-term fundamental knowledge of the processes that transport, modify, concentrate, and emplace (1) the energy and mineral resources of the earth and (2) the energy byproducts of man. The Program is divided into five broad categories: Geophysics and earth dynamics; Geochemistry; Energy resource recognition, evaluation, and utilization; Hydrogeology and exogeochemistry; and Solar-terrestrial interactions. The summaries in this document, prepared by the investigators, describe the scopemore » of the individual programs in these main areas and their subdivisions including earth dynamics, properties of earth materials, rock mechanics, underground imaging, rock-fluid interactions, continental scientific drilling, geochemical transport, solar/atmospheric physics, and modeling, with emphasis on the interdisciplinary areas.« less

Closing the Geoscience Talent Gap

NASA Astrophysics Data System (ADS)

Keane, C. M.

2007-12-01

The geosciences, like most technical professions, are facing a critical talent gap into the future, with too few new students entering the profession and too many opportunities for that supply. This situation has evolved as a result of multiple forces, including increased commodity prices, greater strain on water resources, development encroachment on hazardous terrain, and the attrition of Baby Boomers from the workforce. Demand is not the only issue at hand, the legacy of lagging supplies of new students and consequently new professionals has enhanced the problem. The supply issue is a result of the fallout from the 1986 oil bust and the unsubstantiated hopes for an environmental boom in the 1990"s, coupled by the lengthening of academic careers, indefinitely delaying the predicted exodus of faculty. All of these issues are evident in the data collected by AGI, its Member Societies, and the federal government. Two new factors are beginning to play an increased role in the success or failure of geosciences programs: namely student attitudes towards careers and the ability for departments to successfully bridge the demands of the incoming student with the requirements for an individual to succeed in the profession. An issue often lost for geosciences departments is that 95% of geoscientists in the United States work in the private sector or for government agencies, and that those employers drive the profession forward in the long term. Departments that manage to balance the student needs with an end source of gainful employment are witnessing great success and growth. Currently, programs with strong roots in mining, petroleum, and groundwater hydrology are booming, as are graduate programs with strong technology components. The challenge is recognizing the booms, busts, and long-term trends and positioning programs to weather the changes yet retain the core of their program. This level of planning coupled with a profession-wide effort to improve initial recruitment, greater throughput of graduates into the profession, and the development of professionalism for majors will be central to the geosciences future success.

Initial Results from the STEM Student Experiences Aboard Ships (STEMSEAS) Program

NASA Astrophysics Data System (ADS)

Lewis, J. C.; Cooper, S. K.; Thomson, K.; Rabin, B.; Alberts, J.

2016-12-01

The Science Technology Engineering and Math Student Experiences Aboard Ships (STEMSEAS) program was created as a response to NSF's call (through GEOPATHS) for improving undergraduate STEM education and enhancing diversity in the geosciences. It takes advantage of unused berths on UNOLS ships during transits between expeditions. During its 2016 pilot year - which consisted of three transits on three different research vessels in different parts of the country, each with a slightly different focus - the program has gained significant insights into how best to create and structure these opportunities and create impact on individual students. A call for applications resulted in nearly 900 applicants for 30 available spots. Of these applicants, 32% are from minority groups underrepresented in the geosciences (Black, Hispanic, or American Indian) and 20% attend community colleges. The program was able to sail socioeconomically diverse cohorts and include women, veterans, and students with disabilities and from two- and four-year colleges. Twenty-three are underrepresented minorities, 6 attend community colleges, 5 attend an HBCU or tribal college, and many are at HSIs or other MSIs. While longer term impact assessment will have to wait, initial results and 6-month tracking for the first cohort indicate that these kinds of relatively short but intense experiences can indeed achieve significant impacts on students' perception of the geosciences, in their understanding of STEM career opportunities, their desire to work in a geoscience lab setting, and to incorporate geosciences into non-STEM careers. Insights were also gained into the successful makeup of mentor/leader groups, factors to consider in student selection, necessary pre- and post-cruise logistics management, follow-up activities, structure of activities during daily life at sea, increasing student networks and access to mentorships, and leveraging of pre-existing resources and ship-based opportunities. Additionally, lessons learned by working with multiple UNOLS ship operators can be applied to the growth of the program over time.

NASA Applied Sciences' DEVELOP National Program: a unique model cultivating capacity in the geosciences

NASA Astrophysics Data System (ADS)

Ross, K. W.; Favors, J. E.; Childs-Gleason, L. M.; Ruiz, M. L.; Rogers, L.; Allsbrook, K. N.

2013-12-01

The NASA DEVELOP National Program takes a unique approach to cultivating the next generation of geoscientists through interdisciplinary research projects that address environmental and public policy issues through the application of NASA Earth observations. Competitively selected teams of students, recent graduates, and early career professionals take ownership of project proposals outlining basic application concepts and have ten weeks to research core scientific challenges, engage partners and end-users, demonstrate prototypical solutions, and finalize and document their results and outcomes. In this high pressure, results-driven environment emerging geoscience professionals build strong networks, hone effective communication skills, and learn how to call on the varied strengths of a multidisciplinary team to achieve difficult objectives. The DEVELOP approach to workforce development has a variety of advantages over classic apprenticeship-style internship systems. Foremost is the experiential learning of grappling with real-world applied science challenges as a primary actor instead of as an observer or minor player. DEVELOP participants gain experience that fosters personal strengths and service to others, promoting a balance of leadership and teamwork in order to successfully address community needs. The program also advances understanding of Earth science data and technology amongst participants and partner organizations to cultivate skills in managing schedules, risks and resources to best optimize outcomes. Individuals who come through the program gain experience and networking opportunities working within NASA and partner organizations that other internship and academic activities cannot replicate providing not only skill development but an introduction to future STEM-related career paths. With the competitive nature and growing societal role of science and technology in today's global community, DEVELOP fosters collaboration and advances environmental understanding by promoting and improving the ability of the future geoscience workforce to recognize, understand, and address environmental issues facing the Earth.

A Modern Approach to the Traditional Textbook: Bringing Introductory Geology Courses into the 21st Century

NASA Astrophysics Data System (ADS)

Workman Ford, K.; Ford, K. R.

2013-12-01

Undergraduate introductory geology courses are required in many colleges nationwide as part of the general education requirement. As a result, a large portion of those students are non-majors and most are not science majors. Textbooks used in these courses are often extensive with respect to the amount of material covered which tends to be overwhelming to the average student. Thus, students often purchase the pricey textbook but turn to their smartphones, notebooks, and laptops for answers. Before the development of the internet, students spent many hours in libraries and with their textbooks organizing and retrieving information. However, new technologies in the 21st century have essentially replaced traditional textbooks with students turning to online search engines, such as Google, to study and to complete homework assignments. Presently, online search engines may be more intuitive, but what's going on in the background isn't intuitive at all, and few students have a clear understanding of how search engines operate. Effectively this leads to students without the conception of how to build an adequate search strategy independent of search engines. Often, students are directed to online encyclopedias that may have erroneous information. Here, we employ an alternative to traditional textbooks and online search engines by implementing a guidebook with electronic resources for online activities and homework assignments. The proposed guidebook is roughly modeled after the American Geosciences Institute's Geoscience Handbook: AGI Data Sheets 4th, revised edition, and will include diagrams, graphs, charts, and pictures of basic geologic principles, processes, and earth materials. Along with the information, each topic will have online resources including sites for general reading, specific assignments that require visiting scientifically sound websites (i.e., USGS, GSA, AGU, Science, Nature), online self-assessment activities, and Google Earth activities. In addition, some elements would include a critical thinking problem wherein students research a topic without specific online resources provided, and compare what they find to reputable resources. This process is likely to drive students to evaluate their sources in a more critical manner. Given that textbooks are costly and sometimes overwhelming for students compelling them to use online search engines, the idea of a guidebook that encompasses electronic resources may engage the students more effectively, leading to a more comprehensive understanding and appreciation of the geosciences.

What can They do When we Give Them the Chance? Assessing the Impact of Data- Immersive Technology-Enabled Inquiry Projects on High School Students' Understanding of Geoscience

NASA Astrophysics Data System (ADS)

Zalles, D.; Quellmalz, E.; Gobert, J.; Pallant, A.

2006-12-01

The report "Bringing Research on Learning to the Geosciences" (Manduca, Mogk, & Stillings, 2002) proposed a new program of research to invigorate and expand geoscience education. The report recommended integrating best practices in learning science with the distinctive challenges posed by using geoscience data sets and visualizations in inquiry activities (e.g., working with geologic time-referenced concepts, observing complex natural systems, using integrative and synthetic approaches). Geoscience educators are challenged with how to take advantage of publicly available data and visualization technology to build in their students deeper understanding of key Earth system phenomena and, at the same time, greater ability to identify and generate appropriate inquiry strategies. Their challenge is made greater by the fact that the ways in which geoscientists design research studies and represent, interpret, and analyze data vary widely with the disparate Earth system phenomena they study. Data for example, that permit analysis of the relationships between plate boundaries and earthquakes have quite different representational requirements than weather data that support analyses of climate change. The data's spatial and temporal characteristics are also critical determinants of representational requirements. How can students be led to appreciate what is knowable and not knowable by specific data sets, and how can they become better at taking the best possible advantages of whatever data are available to them as they formulate research questions and confront authentic problems? These are the questions we are addressing in our NSF-funded project, Data Sets and Inquiry in Geoscience Education. We are investigating what greater understandings of epistemically-appropriate geoscientifc inquiry high school students are capable of demonstrating when provided with the opportunity. To do this, we are designing and testing data-immersive project-based units that supplement existing geoscience curriculum programs. The units provide extended multi-day inquiry-based investigations centered on real geoscience data sets and data visualizations. The performance assessments provide evidence of geoscience knowledge and inquiry strategies seldom captured in traditional test formats. In the assessments, students apply the inquiry they practiced in the units to similar yet contrasting problems. We have chosen to focus on the highly-contrasting subjects of geology and climatology. In the geology unit, the students use a time-based simulation tool that provides three-dimensional data about earthquakes around the world in order to explore their relationship to the characteristics of plate boundaries in the Earth's crust. In the climatology unit, the students compare historical climate data about a particular city in relation to its state, to other communities in its state, and to North America in order to draw conclusions about the extent to which the characteristics of local climate change mirror what is happening elsewhere. They think critically about what can and cannot be known from the available data and conceptualize what would be a more ideal research study if sufficient resources were available. In our presentation, we will report on the progress we have made developing and pilot testing the units and assessments in high school classrooms. We will also report preliminary results and describe rubrics we have devised to assess the results.

Expanding the Horizon: A Journey to Explore and Share Effective Geoscience Research Experiences

NASA Astrophysics Data System (ADS)

Bolman, J.

2013-12-01

The Indian Natural Resource Science and Engineering Program (INRSEP) has worked diligently over the past 40 + years to ensure the success of Tribal, Indigenous and Underrepresented undergraduate and graduate students in geoscience and natural resources fields of study. Central to this success has been the development of cultural relevant research opportunities directed by Tribal people. The research experiences have been initiated to address culturally relevant challenges on Tribal and non-Tribal lands. It has become critically important to ensure students have multiple research experiences across North America as well as throughout the continent. The INRSEP community has found creating and maintaining relationships with organizations like the Geoscience Alliance, Minorities Striving and Pursuing Higher Degrees of Success (MSPHD's) and the Louis Stokes Alliance for Minority Participation (LSAMP) program has greatly improved the success of students matriculating to graduate STEM programs. These relationships also serve an immense capacity in tracking students, promoting best practices in research development and assessing outcomes. The presentation will highlight lessons learned on how to 1) Develop a diverse cohort or 'community' of student researchers; 2) Evolve intergenerational mentoring processes and outcomes; 3) Tether to related research and programs; and Foster the broader impact of geoscience research and outcomes.

Resources to Transform Undergraduate Geoscience Education: Activities in Support of Earth, Oceans and Atmospheric Sciences Faculty, and Future Plans

NASA Astrophysics Data System (ADS)

Ryan, J. G.; Singer, J.

2013-12-01

The NSF offers funding programs that support geoscience education spanning atmospheric, oceans, and Earth sciences, as well as environmental science, climate change and sustainability, and research on learning. The 'Resources to Transform Undergraduate Geoscience Education' (RTUGeoEd) is an NSF Transforming Undergraduate Education in STEM (TUES) Type 2 special project aimed at supporting college-level geoscience faculty at all types of institutions. The project's goals are to carry out activities and create digital resources that encourage the geoscience community to submit proposals that impact their courses and classroom infrastructure through innovative changes in instructional practice, and contribute to making transformative changes that impact student learning outcomes and lead to other educational benefits. In the past year information sessions were held during several national and regional professional meetings, including the GSA Southeastern and South-Central Section meetings. A three-day proposal-writing workshop for faculty planning to apply to the TUES program was held at the University of South Florida - Tampa. During the workshop, faculty learned about the program and key elements of a proposal, including: the need to demonstrate awareness of prior efforts within and outside the geosciences and how the proposed project builds upon this knowledge base; need to fully justify budget and role of members of the project team; project evaluation and what matters in selecting a project evaluator; and effective dissemination practices. Participants also spent time developing their proposal benefitting from advice and feedback from workshop facilitators. Survey data gathered from workshop participants point to a consistent set of challenges in seeking grant support for a desired educational innovation, including poor understanding of the educational literature, of available funding programs, and of learning assessment and project evaluation. Many also noted that their institutions did not recognize the value of education-related scholarly activities, or undervaluing it compared to more traditional research activities. Given this reality, faculty desire strategies for balancing their time to allow time to pursue both. The current restructuring of NSF educational programs raises questions regarding future directions and the scale of support that may be available from the proposed Catalyzing Advances in Undergraduate STEM Education (CAUSE) Program. At the time of writing this abstract, specific details have not been communicated, but it appears that CAUSE could encompass components from several programs within the Division of Undergraduate Education's TUES, STEP, and WIDER programs, as well as the Geoscience Education and OEDG programs in the Geosciences Directorate. The RTUGeoEd project will continue to provide support to faculty seeking CAUSE (and other educational funding within DUE).

On the Cutting Edge Professional Development Program: Workshop and Web Resources for Current and Future Geoscience Faculty

NASA Astrophysics Data System (ADS)

MacDonald, R.; Manduca, C. A.; Mogk, D. W.; Tewksbury, B. J.

2004-12-01

Recognizing that many college and university faculty receive little formal training in teaching, are largely unaware of advances in research on teaching and learning, and face a variety of challenges in advancing in academic careers, the National Science Foundation-funded program On the Cutting Edge provides professional development for current and future faculty in the geosciences at various stages in their careers. The program includes a series of six multi-day workshops, sessions and one-day workshops at professional meetings, and a website with information about workshop opportunities and a variety of resources that bring workshop content to faculty (http://serc.carleton.edu/NAGTWorkshops). The program helps faculty improve their teaching and their job satisfaction by providing resources on instructional methods, geoscience content, and strategies for career planning. Workshop and website resources address innovative and effective practices in teaching, course design, delivery of instructional materials, and career planning, as well as approaches for teaching particular topics and strategies for starting and maintaining a research program in various institutional settings. Each year, special workshops for graduate students and post-doctoral fellows interested in academic careers and for early career faculty complement offerings on course design and emerging topics that are open to the full geoscience community. These special workshops include sessions on topics such as dual careers, gender issues, family-work balance, interviewing and negotiating strategies. The workshops serve as opportunities for networking and community building, with participants building connections with other participants as well as workshop leaders. Workshop participants reflect the full range of institutional diversity as well as ethnic and racial diversity beyond that of the geoscience faculty workforce. More than 40 percent of the faculty participants are female. Of the faculty participants in workshops offered July 2002 through June 2004, workshop participants have come from more than 250 colleges and universities in 49 states and the District of Columbia. Workshop evaluations indicate that the workshops are well received with faculty particularly appreciating the content of the workshops and the opportunities for networking. An important aspect of the program is involvement of the geoscience community in workshop leadership. Leadership roles include serving as co-conveners, invited speakers, demonstration leaders, working group leaders, co-conveners of post-workshop sessions at professional meetings, and contributors to the website.

Virtual Workshop Experiences for Faculty: Lessons Learned from On the Cutting Edge

NASA Astrophysics Data System (ADS)

McDaris, J. R.; Kirk, K. B.; Mogk, D. W.; Bruckner, M. Z.

2010-12-01

The On the Cutting Edge professional development program for geoscience faculty has begun offering online workshops as a supplement to its face-to-face workshop series. Following a few initial forays since 2005, Cutting Edge launched a suite of four virtual workshops in 2010: Teaching Geoscience with Service Learning, Understanding the Deep Earth, Designing Effective and Innovative Courses in the Geosciences, and Teaching Geoscience Online. Each workshop was presented over 1-2 weeks and included pre-workshop web postings, synchronous whole-group presentations, live small-group discussions, asynchronous input via threaded discussions or editable web pages, and personal time for reflection and writing. Synchronous sessions were facilitated through the Elluminate software platform which includes tools for viewing presentations, screen sharing, real-time participant response, and an ongoing chat-room discussion. Audio was provided through a separate telephone conference service. In addition, many asynchronous conversations on workshop topics were held via a threaded discussion board on the Cutting Edge website and in Wiki-like, editable web pages designed to support collaborative work. A number of challenges to running online workshops exist, primarily involving participants’ time management. It is difficult for participants to set aside enough time to complete workshop activities when they are still enmeshed in their everyday lives. It also requires new skills for speakers, participants and support staff to prepare web-based materials and navigate the technology required for the online presentations. But there are also a number of opportunities presented by these experiences. With no travel needed, an online workshop is less expensive for participants, which allows Cutting Edge to extend its commitment to providing workshop materials to a wider audience of interested faculty. Also, synchronous sessions can be recorded and posted on the website for broader community access. In terms of best practices, the most important lesson learned is the need to make the experience as “real” as possible so that participants stay engaged and feel connected to the workshop experience. This can be accomplished by making the presentations interactive, continued leader participation in threaded discussions and break out groups, and providing multiple channels for contribution and participation. Despite some initial hesitation in jumping into a virtual environment, participants gained experience and became more comfortable with collaboration via online technologies. Participants had access to their own scientific and instructional materials at their home offices, and as a result could design and complete new teaching resources more effectively during the workshop. Peer review of new instructional resources was also completed during the workshop, and virtual networks were established to support continuing work. Online workshops can be used to effectively minimize costs, extend participation, build and sustain community networks, and develop thematic collections of instructional resources and activities. Based on the success of the 2010 workshops, more online workshops are planned for the coming years.

Teaching Resources and Instructor Professional Development for Integrating Laser Scanning, Structure from Motion, and GPS Surveying into Undergraduate Field Courses

NASA Astrophysics Data System (ADS)

Pratt-Sitaula, B.; Charlevoix, D. J.; Douglas, B. J.; Crosby, B. T.; Crosby, C. J.; Lauer, I. H.; Shervais, K.

2017-12-01

Field experiences have long been considered an integral part of geoscience learning. However, as data acquisition technologies evolve, undergraduate field courses need to keep pace so students gain exposure to new technologies relevant to the modern workforce. Maintaining expertise on new technologies is also challenging to established field education programs. Professional development and vetted curriculum present an opportunity to advance student exposure to new geoscience data acquisition technology. The GEodesy Tools for Societal Issues (GETSI) Field Collection, funded by NSF's Improving Undergraduate STEM Education program, addresses these needs in geodesy field education. Geodesy is the science of accurately measuring Earth's size, shape, orientation, mass distribution and the variations of these with time. Modern field geodesy methods include terrestrial laser scanning (TLS), kinematic and static GPS/GNSS surveying (global positioning system/global navigation satellite system), and structure from motion (SfM) photogrammetry. The GETSI Field Collection is a collaborative project between UNAVCO, Indiana University, and Idaho State University. The project is provides curriculum modules and instructor training (in the form of short courses) to facilitate the inclusion of SfM, TLS, and GPS surveying into geoscience courses with field components. The first module - Analyzing High Resolution Topography with TLS and SfM - is available via SERC; (serc.carleton.edu/getsi/teaching_materials/high-rez-topo) the second module - "High Precision Positioning with Static and Kinematic GPS/GNSS" - will be published in 2018. The module development and assessment follows the standards of the InTeGrate Project (an NSF STEP Center)previously tested on geodesy content in the GETSI classroom collection (serc.carleton.edu/getsi). This model emphasizes use of best practices in STEM education, including situating learning in the context of societal importance. Analysis of student work during development and testing shows a high level of achievement of module learning goals. Two four-day short courses have been run to train instructors on best practices for integration of these topics into field courses. Overall participant satisfaction with the short courses has been 9 out of 10.

Consortium for Mathematics in the Geosciences (CMG++): Promoting the application of mathematics, statistics, and computational sciences to the geosciences

NASA Astrophysics Data System (ADS)

Mead, J.; Wright, G. B.

2013-12-01

The collection of massive amounts of high quality data from new and greatly improved observing technologies and from large-scale numerical simulations are drastically improving our understanding and modeling of the earth system. However, these datasets are also revealing important knowledge gaps and limitations of our current conceptual models for explaining key aspects of these new observations. These limitations are impeding progress on questions that have both fundamental scientific and societal significance, including climate and weather, natural disaster mitigation, earthquake and volcano dynamics, earth structure and geodynamics, resource exploration, and planetary evolution. New conceptual approaches and numerical methods for characterizing and simulating these systems are needed - methods that can handle processes which vary through a myriad of scales in heterogeneous, complex environments. Additionally, as certain aspects of these systems may be observable only indirectly or not at all, new statistical methods are also needed. This type of research will demand integrating the expertise of geoscientist together with that of mathematicians, statisticians, and computer scientists. If the past is any indicator, this interdisciplinary research will no doubt lead to advances in all these fields in addition to vital improvements in our ability to predict the behavior of the planetary environment. The Consortium for Mathematics in the Geosciences (CMG++) arose from two scientific workshops held at Northwestern and Princeton in 2011 and 2012 with participants from mathematics, statistics, geoscience and computational science. The mission of CMG++ is to accelerate the traditional interaction between people in these disciplines through the promotion of both collaborative research and interdisciplinary education. We will discuss current activities, describe how people can get involved, and solicit input from the broader AGU community.

Geospatial data infrastructure: The development of metadata for geo-information in China

NASA Astrophysics Data System (ADS)

Xu, Baiquan; Yan, Shiqiang; Wang, Qianju; Lian, Jian; Wu, Xiaoping; Ding, Keyong

2014-03-01

Stores of geoscience records are in constant flux. These stores are continually added to by new information, ideas and data, which are frequently revised. The geoscience record is in restrained by human thought and technology for handling information. Conventional methods strive, with limited success, to maintain geoscience records which are readily susceptible and renewable. The information system must adapt to the diversity of ideas and data in geoscience and their changes through time. In China, more than 400,000 types of important geological data are collected and produced in geological work during the last two decades, including oil, natural gas and marine data, mine exploration, geophysical, geochemical, remote sensing and important local geological survey and research reports. Numerous geospatial databases are formed and stored in National Geological Archives (NGA) with available formats of MapGIS, ArcGIS, ArcINFO, Metalfile, Raster, SQL Server, Access and JPEG. But there is no effective way to warrant that the quality of information is adequate in theory and practice for decision making. The need for fast, reliable, accurate and up-to-date information by providing the Geographic Information System (GIS) communities are becoming insistent for all geoinformation producers and users in China. Since 2010, a series of geoinformation projects have been carried out under the leadership of the Ministry of Land and Resources (MLR), including (1) Integration, update and maintenance of geoinformation databases; (2) Standards research on clusterization and industrialization of information services; (3) Platform construction of geological data sharing; (4) Construction of key borehole databases; (5) Product development of information services. "Nine-System" of the basic framework has been proposed for the development and improvement of the geospatial data infrastructure, which are focused on the construction of the cluster organization, cluster service, convergence, database, product, policy, technology, standard and infrastructure systems. The development of geoinformation stores and services put forward a need for Geospatial Data Infrastructure (GDI) in China. In this paper, some of the ideas envisaged into the development of metadata in China are discussed.

Developing a Program to Increase Diversity in the Geosciences

NASA Astrophysics Data System (ADS)

Prendeville, J. C.

2001-05-01

The Geosciences have a history of poor participation by minorities- African Americans, Hispanics, Native Americans and persons with disabilities. Demographic data concerning population trends over the next decades make it clear that, without intervention, underrepresentation of these groups in the geosciences will only worsen. The Directorate for Geosciences of the National Science Foundation has acknowledged the problem of underrepresentation and the loss of intellectual resources that it represents. The Directorate has established a program to create a pool of students from underrepresented groups who will take their place in the future as both scientific researchers and educators, as well as scientifically knowledgeable citizens. The strategy employed in developing the Geosciences Diversity program emphasizes community direction and inclusion. Steps in developing the program included examining data that demonstrate where the "leaks" in the educational pipeline occur; reviewing the programs that are offered by the NSF, by other federal agencies and by professional societies; and gaining insights from individuals who have developed or managed programs that have similar goals.

EarthConnections: Integrating Community Science and Geoscience Education Pathways for More Resilient Communities.

NASA Astrophysics Data System (ADS)

Manduca, C. A.

2017-12-01

To develop a diverse geoscience workforce, the EarthConnections collective impact alliance is developing regionally focused, Earth education pathways. These pathways support and guide students from engagement in relevant, Earth-related science at an early age through the many steps and transitions to geoscience-related careers. Rooted in existing regional activities, pathways are developed using a process that engages regional stakeholders and community members with EarthConnections partners. Together they connect, sequence, and create multiple learning opportunities that link geoscience education and community service to address one or more local geoscience issues. Three initial pilots are demonstrating different starting points and strategies for creating pathways that serve community needs while supporting geoscience education. The San Bernardino pilot is leveraging existing academic relationships and programs; the Atlanta pilot is building into existing community activities; and the Oklahoma Tribal Nations pilot is co-constructing a pathway focus and approach. The project is using pathway mapping and a collective impact framework to support and monitor progress. The goal is to develop processes and activities that can help other communities develop similar community-based geoscience pathways. By intertwining Earth education with local community service we aspire to increase the resilience of communities in the face of environmental hazards and limited Earth resources.

Collaboration and Perspectives on Identity Management and Access from two Geoscience Cyberinfrastructure Programs

NASA Astrophysics Data System (ADS)

Ramamurthy, M. K.

2016-12-01

Increasingly, the conduct of science requires close international collaborations to share data, information, knowledge, expertise, and other resources. This is particularly true in the geosciences where the highly connected nature of the Earth system and the need to understand global environmental processes have heightened the importance of scientific partnerships. As geoscience studies become a team effort involving networked scientists and data providers, it is crucial that there is open and reliable access to earth system data of all types, software, tools, models, and other assets. That environment demands close attention to security-related matters, including the creation of trustworthy cyberinfrastructure to facilitate the efficient use of available resources and support the conduct of science. Unidata and EarthCube, both of which are NSF-funded and community-driven programs, recognize the importance of collaborations and the value of networked communities. Unidata, a cornerstone cyberinfrastructure facility for the geosciences, includes users in nearly 180 countries. The EarthCube initiative is aimed at transforming the conduct of geosciences research by creating a well-connected and facile environment for sharing data and in an open, transparent, and inclusive manner and to accelerate our ability to understand and predict the Earth system. We will present the Unidata and EarthCube community perspectives on the approaches to balancing an environment that promotes open and collaborative eScience with the needs for security and communication, including what works, what is needed, the challenges, and opportunities to advance science.

Workshop for Early Career Geoscience Faculty: Providing resources and support for new faculty to succeed

NASA Astrophysics Data System (ADS)

Hill, T. M.; Beane, R. J.; Macdonald, H.; Manduca, C. A.; Tewksbury, B. J.; Allen-King, R. M.; Yuretich, R.; Richardson, R. M.; Ormand, C. J.

2015-12-01

A vital strategy to educate future geoscientists is to support faculty at the beginning of their careers, thus catalyzing a career-long impact on the early-career faculty and on their future students. New faculty members are at a pivotal stage in their careers as they step from being research-focused graduate students and post-doctoral scholars, under the guidance of advisors, towards launching independent careers as professors. New faculty commonly, and not unexpectedly, feel overwhelmed as they face challenges to establish themselves in a new environment, prepare new courses, begin new research, and develop a network of support. The workshop for Early Career Geoscience Faculty: Teaching, Research, and Managing Your Career has been offered annually in the U.S. since 1999. The workshop is currently offered through the National Association of Geoscience Teachers On the Cutting Edge professional development program with support from the NSF, AGU and GSA. This five-day workshop, with associated web resources, offers guidance for incorporating evidence-based teaching practices, developing a research program, and managing professional responsibilities in balance with personal lives. The workshop design includes plenary and concurrent sessions, individual consultations, and personalized feedback from workshop participants and leaders. Since 1999, more than 850 U.S. faculty have attended the Early Career Geoscience Faculty workshop. Participants span a wide range of geoscience disciplines, and are in faculty positions at two-year colleges, four-year colleges, comprehensive universities and research universities. The percentages of women (~50%) and underrepresented participants (~8%) are higher than in the general geoscience faculty population. Multiple participants each year are starting positions after receiving all or part of their education outside the U.S. Collectively, participants report that they are better prepared to move forward with their careers as a result of the workshop, that they plan to incorporate evidence-based teaching in their classrooms, and that they leave the workshop with a network of support and the resources needed to enable them succeed. http://serc.carleton.edu/NAGTWorkshops/earlycareer

The Challenges and Benefits of Using Computer Technology for Communication and Teaching in the Geosciences

NASA Astrophysics Data System (ADS)

Fairley, J. P.; Hinds, J. J.

2003-12-01

The advent of the World Wide Web in the early 1990s not only revolutionized the exchange of ideas and information within the scientific community, but also provided educators with a new array of teaching, informational, and promotional tools. Use of computer graphics and animation to explain concepts and processes can stimulate classroom participation and student interest in the geosciences, which has historically attracted students with strong spatial and visualization skills. In today's job market, graduates are expected to have knowledge of computers and the ability to use them for acquiring, processing, and visually analyzing data. Furthermore, in addition to promoting visibility and communication within the scientific community, computer graphics and the Internet can be informative and educational for the general public. Although computer skills are crucial for earth science students and educators, many pitfalls exist in implementing computer technology and web-based resources into research and classroom activities. Learning to use these new tools effectively requires a significant time commitment and careful attention to the source and reliability of the data presented. Furthermore, educators have a responsibility to ensure that students and the public understand the assumptions and limitations of the materials presented, rather than allowing them to be overwhelmed by "gee-whiz" aspects of the technology. We present three examples of computer technology in the earth sciences classroom: 1) a computer animation of water table response to well pumping, 2) a 3-D fly-through animation of a fault controlled valley, and 3) a virtual field trip for an introductory geology class. These examples demonstrate some of the challenges and benefits of these new tools, and encourage educators to expand the responsible use of computer technology for teaching and communicating scientific results to the general public.

Collaboration Among Educators: An Essential Step in Unifying STEM Teaching Resources.

NASA Astrophysics Data System (ADS)

McIver, H.; Ellins, K. K.; Bohls-Graham, C. E.; O'dell, D.; Sergent, C.; Jacobs, B. E.; Stocks, E.; Serpa, L. F.; Riggs, E. M.

2015-12-01

Increased requirement for Science, Engineering, Technology, and Math (STEM) literacy among US secondary school students has enhanced the need for high-quality teaching resources in the modern STEM classroom. Many relevant resources exist online that could be used to address this issue, but too often these resources are spread throughout the Internet, and have not necessarily been audited for content, alignment with state and national science standards, or current functionality. Because STEM subjects are increasingly difficult to teach, we set out to design a localized platform of year-long teaching 'blueprints' comprising units that cover a range of Earth science topics, researched and compiled by education professionals. The Diversity and Innovation for Geosciences (DIG) Texas Instructional Blueprint project has united teachers from diverse science backgrounds who act as Education Interns and work alongside geoscientists and curriculum experts at the University of Texas Jackson School of Geosciences, Texas A&M University and the University of Texas El Paso. Our DIG collective has employed a cross-disciplinary approach to vetting resources while compiling them in useful, logical sequences for classroom instruction. The DIG team has aligned each blueprint with the Texas Essential Skills and Knowledge (TEKS) standards for Earth and Space Science, the Earth Science Literacy Principles, and the Next Generation Science Standards. Emphasis for the summer 2015 project group was placed upon (1) alignment of the units with these three sets of science standards to allow for use within disparate classroom settings, (2) creating teacher aides including scaffolding notes for practical unit application, and potential real and virtual field trips for unit illustration, and (3) final vetting ensuring units follow a narrative that carries learners from basic principles to a full concept understanding. Here, we present our progress and the essential workflow that has contributed to significant advancement in our goal of providing a unified STEM teaching resource.

CINERGI: Community Inventory of EarthCube Resources for Geoscience Interoperability

NASA Astrophysics Data System (ADS)

Zaslavsky, Ilya; Bermudez, Luis; Grethe, Jeffrey; Gupta, Amarnath; Hsu, Leslie; Lehnert, Kerstin; Malik, Tanu; Richard, Stephen; Valentine, David; Whitenack, Thomas

2014-05-01

Organizing geoscience data resources to support cross-disciplinary data discovery, interpretation, analysis and integration is challenging because of different information models, semantic frameworks, metadata profiles, catalogs, and services used in different geoscience domains, not to mention different research paradigms and methodologies. The central goal of CINERGI, a new project supported by the US National Science Foundation through its EarthCube Building Blocks program, is to create a methodology and assemble a large inventory of high-quality information resources capable of supporting data discovery needs of researchers in a wide range of geoscience domains. The key characteristics of the inventory are: 1) collaboration with and integration of metadata resources from a number of large data facilities; 2) reliance on international metadata and catalog service standards; 3) assessment of resource "interoperability-readiness"; 4) ability to cross-link and navigate data resources, projects, models, researcher directories, publications, usage information, etc.; 5) efficient inclusion of "long-tail" data, which are not appearing in existing domain repositories; 6) data registration at feature level where appropriate, in addition to common dataset-level registration, and 7) integration with parallel EarthCube efforts, in particular focused on EarthCube governance, information brokering, service-oriented architecture design and management of semantic information. We discuss challenges associated with accomplishing CINERGI goals, including defining the inventory scope; managing different granularity levels of resource registration; interaction with search systems of domain repositories; explicating domain semantics; metadata brokering, harvesting and pruning; managing provenance of the harvested metadata; and cross-linking resources based on the linked open data (LOD) approaches. At the higher level of the inventory, we register domain-wide resources such as domain catalogs, vocabularies, information models, data service specifications, identifier systems, and assess their conformance with international standards (such as those adopted by ISO and OGC, and used by INSPIRE) or de facto community standards using, in part, automatic validation techniques. The main level in CINERGI leverages a metadata aggregation platform (currently Geoportal Server) to organize harvested resources from multiple collections and contributed by community members during EarthCube end-user domain workshops or suggested online. The latter mechanism uses the SciCrunch toolkit originally developed within the Neuroscience Information Framework (NIF) project and now being extended to other communities. The inventory is designed to support requests such as "Find resources with theme X in geographic area S", "Find datasets with subject Y using query concept expansion", "Find geographic regions having data of type Z", "Find datasets that contain property P". With the added LOD support, additional types of requests, such as "Find example implementations of specification X", "Find researchers who have worked in Domain X, dataset Y, location L", "Find resources annotated by person X", will be supported. Project's website (http://workspace.earthcube.org/cinergi) provides access to the initial resource inventory, a gallery of EarthCube researchers, collections of geoscience models, metadata entry forms, and other software modules and inventories being integrated into the CINERGI system. Support from the US National Science Foundation under award NSF ICER-1343816 is gratefully acknowledged.

Helping Educators Find Visualizations and Teaching Materials Just-in-Time

NASA Astrophysics Data System (ADS)

McDaris, J.; Manduca, C. A.; MacDonald, R. H.

2005-12-01

Major events and natural disasters like hurricanes and tsunamis provide geoscience educators with powerful teachable moments to engage their students with class content. In order to take advantage of these opportunities, educators need quality topical resources related to current earth science events. The web has become an excellent vehicle for disseminating this type of resource. In response to the 2004 Indian Ocean Earthquake and to Hurricane Katrina's devastating impact on the US Gulf Coast, the On the Cutting Edge professional development program developed collections of visualizations for use in teaching. (serc.carleton.edu/NAGTWorkshops/visualization/collections/ tsunami.html,serc.carleton.edu/NAGTWorkshops/visualization/ collections/hurricanes.html). These sites are collections of links to visualizations and other materials that can support the efforts of faculty, teachers, and those engaged in public outreach. They bring together resources created by researchers, government agencies and respected media sources and organize them for easy use by educators. Links are selected to provide a variety of different types of visualizations (e.g photographic images, animations, satellite imagery) and to assist educators in teaching about the geologic event reported in the news, associated Earth science concepts, and related topics of high interest. The cited links are selected from quality sources and are reviewed by SERC staff before being included on the page. Geoscience educators are encouraged to recommend links and supporting materials and to comment on the available resources. In this way the collection becomes more complete and its quality is enhanced.. These sites have received substantial use (Tsunami - 77,000 visitors in the first 3 months, Hurricanes - 2500 visitors in the first week) indicating that in addition to use by educators, they are being used by the general public seeking information about the events. Thus they provide an effective mechanism for guiding the public to quality resources created by geoscience researchers and facilities, in addition to supporting incorporation of geoscience research in education.

On the Cutting Edge: Workshops, Online Resources, and Community Development

NASA Astrophysics Data System (ADS)

Mogk, D. W.; Macdonald, H.; Manduca, C. A.; Tewksbury, B. J.; Fox, S.; Iverson, E. A. R.; Beane, R. J.; Mcconnell, D. A.; Wiese, K.; Wysession, M. E.

2014-12-01

On the Cutting Edge, funded by NSF since 2002, offers a comprehensive professional development program for geoscience faculty. The program includes an annual integrated in-person and virtual workshop series, has developed an extensive collection of peer-reviewed instructional activities and related online resources, and supports continuing community development through sponsorship of webinars, listservs, opportunities for community contributions, and dissemination of resources to keep faculty current in their science and pedagogic practices. On the Cutting Edge (CE) has offered more than 100 face-to-face and virtual workshops, webinars, journal clubs, and other events to more than 3000 participants. The award-winning website has more than 5000 pages including 47 modules on career management, pedagogy, and geoscience topics. It has more than 1800 instructional activities contributed by the community, the majority of which have been peer-reviewed. The website had more than one million visitors last year. We have worked to support a community in which faculty improve their teaching by designing courses using research-based methods to foster higher-order thinking, incorporate geoscience data, and address cognitive and affective aspects of learning as well as a community in which faculty are comfortable and successful in managing their careers. The program addresses the needs of faculty in all career stages at the full spectrum of institutions and covering the breadth of the geoscience curriculum. We select timely and compelling topics that attract different groups of participants. CE workshops are interactive, model best pedagogical practices, emphasize participant learning, provide opportunities for participants to share their knowledge and experience, provide high-quality resources, give participants time to reflect and to develop action plans, and help transform their ideas about teaching. On the Cutting Edge has had an impact on teaching based on data from national surveys, interview and classroom observation studies, and website usage. The Cutting Edge program is now part of the NAGT professional development program that includes face-to-face, traveling, and virtual workshops for faculty and geoscience programs of all types. http://serc.carleton.edu/NAGTWorkshops/index.html

Open Course Ware, Distance Education, and 21st Century Geoscience Education

NASA Astrophysics Data System (ADS)

Connors, M. G.

2010-12-01

Open Course Ware (OCW) allows the highest quality educational materials (including videos of lectures from the best classroom lecturers) to find a wide audience. This audience may include many who wish to obtain credentials for formal study yet who are unable to be campus-based students. This opens a role for formal, credentialed and accredited distance education (DE) to efficiently integrate OCW into DE courses. OCW materials will in this manner be able to be used for education of credential-seeking students who would not otherwise benefit from them. Modern presentation methods using the Internet and video (including mobile device) technologies may offer pedagogical advantages over even traditional classroom learning. A detailed analysis of the development of Athabasca University’s PHYS 302 Vibrations and Waves course (based mainly on MIT’s OCW), and application of lessons learned to development of PHYS 305 Electromagnetism is presented. These courses are relevant to the study of geophysics, but examples of GEOL (Geology) courses will also be mentioned, along with an broad overview of OCW resources in Geoscience.

Teleconferences and Audiovisual Materials in Earth Science Education

NASA Astrophysics Data System (ADS)

Cortina, L. M.

2007-05-01

Unidad de Educacion Continua y a Distancia, Universidad Nacional Autonoma de Mexico, Coyoaca 04510 Mexico, MEXICO As stated in the special session description, 21st century undergraduate education has access to resources/experiences that go beyond university classrooms. However in some cases, resources may go largely unused and a number of factors may be cited such as logistic problems, restricted internet and telecommunication service access, miss-information, etc. We present and comment on our efforts and experiences at the National University of Mexico in a new unit dedicated to teleconferences and audio-visual materials. The unit forms part of the geosciences institutes, located in the central UNAM campus and campuses in other States. The use of teleconference in formal graduate and undergraduate education allows teachers and lecturers to distribute course material as in classrooms. Course by teleconference requires learning and student and teacher effort without physical contact, but they have access to multimedia available to support their exhibition. Well selected multimedia material allows the students to identify and recognize digital information to aid understanding natural phenomena integral to Earth Sciences. Cooperation with international partnerships providing access to new materials and experiences and to field practices will greatly add to our efforts. We will present specific examples of the experiences that we have at the Earth Sciences Postgraduate Program of UNAM with the use of technology in the education in geosciences.

Geoscience information integration and visualization research of Shandong Province, China based on ArcGIS engine

NASA Astrophysics Data System (ADS)

Xu, Mingzhu; Gao, Zhiqiang; Ning, Jicai

2014-10-01

To improve the access efficiency of geoscience data, efficient data model and storage solutions should be used. Geoscience data is usually classified by format or coordinate system in existing storage solutions. When data is large, it is not conducive to search the geographic features. In this study, a geographical information integration system of Shandong province, China was developed based on the technology of ArcGIS Engine, .NET, and SQL Server. It uses Geodatabase spatial data model and ArcSDE to organize and store spatial and attribute data and establishes geoscience database of Shangdong. Seven function modules were designed: map browse, database and subject management, layer control, map query, spatial analysis and map symbolization. The system's characteristics of can be browsed and managed by geoscience subjects make the system convenient for geographic researchers and decision-making departments to use the data.

The OceanLink Project

NASA Astrophysics Data System (ADS)

Narock, T.; Arko, R. A.; Carbotte, S. M.; Chandler, C. L.; Cheatham, M.; Finin, T.; Hitzler, P.; Krisnadhi, A.; Raymond, L. M.; Shepherd, A.; Wiebe, P. H.

2014-12-01

A wide spectrum of maturing methods and tools, collectively characterized as the Semantic Web, is helping to vastly improve the dissemination of scientific research. Creating semantic integration requires input from both domain and cyberinfrastructure scientists. OceanLink, an NSF EarthCube Building Block, is demonstrating semantic technologies through the integration of geoscience data repositories, library holdings, conference abstracts, and funded research awards. Meeting project objectives involves applying semantic technologies to support data representation, discovery, sharing and integration. Our semantic cyberinfrastructure components include ontology design patterns, Linked Data collections, semantic provenance, and associated services to enhance data and knowledge discovery, interoperation, and integration. We discuss how these components are integrated, the continued automated and semi-automated creation of semantic metadata, and techniques we have developed to integrate ontologies, link resources, and preserve provenance and attribution.

The Roles of Working Memory and Cognitive Load in Geoscience Learning

ERIC Educational Resources Information Center

Jaeger, Allison J.; Shipley, Thomas F.; Reynolds, Stephen J.

2017-01-01

Working memory is a cognitive system that allows for the simultaneous storage and processing of active information. While working memory has been implicated as an important element for success in many science, technology, engineering, and mathematics (STEM) fields, its specific role in geoscience learning is not fully understood. The major goal of…

An EarthCube Roadmap for Cross-Domain Interoperability in the Geosciences: Governance Aspects

NASA Astrophysics Data System (ADS)

Zaslavsky, I.; Couch, A.; Richard, S. M.; Valentine, D. W.; Stocks, K.; Murphy, P.; Lehnert, K. A.

2012-12-01

The goal of cross-domain interoperability is to enable reuse of data and models outside the original context in which these data and models are collected and used and to facilitate analysis and modeling of physical processes that are not confined to disciplinary or jurisdictional boundaries. A new research initiative of the U.S. National Science Foundation, called EarthCube, is developing a roadmap to address challenges of interoperability in the earth sciences and create a blueprint for community-guided cyberinfrastructure accessible to a broad range of geoscience researchers and students. Infrastructure readiness for cross-domain interoperability encompasses the capabilities that need to be in place for such secondary or derivative-use of information to be both scientifically sound and technically feasible. In this initial assessment we consider the following four basic infrastructure components that need to be present to enable cross-domain interoperability in the geosciences: metadata catalogs (at the appropriate community defined granularity) that provide standard discovery services over datasets, data access services, models and other resources of the domain; vocabularies that support unambiguous interpretation of domain resources and metadata; services used to access data repositories and other resources including models, visualizations and workflows; and formal information models that define structure and semantics of the information returned on service requests. General standards for these components have been proposed; they form the backbone of large scale integration activities in the geosciences. By utilizing these standards, EarthCube research designs can take advantage of data discovery across disciplines using the commonality in key data characteristics related to shared models of spatial features, time measurements, and observations. Data can be discovered via federated catalogs and linked nomenclatures from neighboring domains, while standard data services can be used to transparently compile composite data products. Key questions addressed in this presentation are: (1) How to define and assess readiness of existing domain information systems for cross-domain re-use? (2) How to determine EarthCube development priorities given a multitude of use cases that involve cross-domain data flows? and (3) How to involve a wider community of geoscientists in the development and curation of cross-domain resources and incorporate community feedback in the CI design? Answering them involves consideration of governance mechanisms for cross-domain interoperability: while domain information systems and projects developed governance mechanisms, managing cross-domain CI resources and supporting cross-domain information re-use hasn't been the development focus at the scale of the geosciences. We present a cross-domain readiness model as enabling effective communication among scientists, governance bodies, and information providers. We also present an initial readiness assessment and a cross-domain connectivity map for the geosciences, and outline processes for eliciting user requirements, setting priorities, and obtaining community consensus.

Examining sexism in the geosciences

NASA Astrophysics Data System (ADS)

Simarski, Lynn Teo

Do women geoscientists face worse obstacles because of their gender than women in other sciences? A recent survey by the Committee on Professionals in Science and Technology showed that women with geoscience bachelor's degrees start off at only 68% of their male colleagues' salaries, much lower than women in biology (92%), engineering (102%), chemistry (103%), and physics (111%).Women still lag behind men in geoscience degrees as well. In 1990, women received about one-third of geoscience bachelor's degrees, one-quarter of masters, and about one-fifth of Ph.D.'s, reports the American Geological Institute. In the sciences overall, women received about half of bachelor's degrees, 42% of masters, and about a third of Ph.D.'s in 1989, according to the National Research Council.

Knowledge Evolution in Distributed Geoscience Datasets and the Role of Semantic Technologies

NASA Astrophysics Data System (ADS)

Ma, X.

2014-12-01

Knowledge evolves in geoscience, and the evolution is reflected in datasets. In a context with distributed data sources, the evolution of knowledge may cause considerable challenges to data management and re-use. For example, a short news published in 2009 (Mascarelli, 2009) revealed the geoscience community's concern that the International Commission on Stratigraphy's change to the definition of Quaternary may bring heavy reworking of geologic maps. Now we are in the era of the World Wide Web, and geoscience knowledge is increasingly modeled and encoded in the form of ontologies and vocabularies by using semantic technologies. Accordingly, knowledge evolution leads to a consequence called ontology dynamics. Flouris et al. (2008) summarized 10 topics of general ontology changes/dynamics such as: ontology mapping, morphism, evolution, debugging and versioning, etc. Ontology dynamics makes impacts at several stages of a data life cycle and causes challenges, such as: the request for reworking of the extant data in a data center, semantic mismatch among data sources, differentiated understanding of a same piece of dataset between data providers and data users, as well as error propagation in cross-discipline data discovery and re-use (Ma et al., 2014). This presentation will analyze the best practices in the geoscience community so far and summarize a few recommendations to reduce the negative impacts of ontology dynamics in a data life cycle, including: communities of practice and collaboration on ontology and vocabulary building, link data records to standardized terms, and methods for (semi-)automatic reworking of datasets using semantic technologies. References: Flouris, G., Manakanatas, D., Kondylakis, H., Plexousakis, D., Antoniou, G., 2008. Ontology change: classification and survey. The Knowledge Engineering Review 23 (2), 117-152. Ma, X., Fox, P., Rozell, E., West, P., Zednik, S., 2014. Ontology dynamics in a data life cycle: Challenges and recommendations from a Geoscience Perspective. Journal of Earth Science 25 (2), 407-412. Mascarelli, A.L., 2009. Quaternary geologists win timescale vote. Nature 459, 624.

Recruiting Fresh Faces: Engaging the Next Generation of Geoscientists

NASA Astrophysics Data System (ADS)

Martinez, C. M.; Keane, C. M.; Gonzales, L. M.

2008-12-01

Approximately 385,000 college students take an introductory geoscience course each year in the United States, according to a study by the American Geological Institute (AGI). This represents only 2.3 percent of the total enrolled higher education population in the US. Though geoscience departments frequently report that introductory geoscience courses are a major source for recruiting new majors, the large numbers of students enrolled in introductory geoscience courses result in only approximately 2,300 new geoscience majors each year, or 0.1 percent of the total college population. According to the College Board, more than 19,000 SAT test-takers in 2007 indicated an interest in pursuing a major in Physical Science, Interdisciplinary Science or Engineering. Forty-nine percent of SAT-takers have had an earth or space science course during high school. There is large pool of college-bound students may be interested in the geosciences, but are unaware of the educational and career opportunities available to them. In an effort to increase the flow of top talent into the geosciences, the American Geological Institute (AGI) launched an ambitious student engagement initiative as part of its Geoscience Workforce Program. This initiative will assist geoscience departments in engaging and recruiting new majors from introductory geoscience courses and will help students connect with the professional community. The academic geoscience community makes up less than 17 percent of the entire geoscience workforce, and many students may not be aware of careers available in other industries and sectors. AGI will make updated careers resources, including diverse employment opportunities, salary potential, and quality of life information, freely available to geoscience instructors for use in their introductory courses. Beginning in Fall 2008, AGI will distribute a New Majors Kit to students in selected geoscience departments. These kits will include tools to help students in their careers, such as access to the Online Glossary of Geology, and will also allow students to join several professional geoscience societies free of charge so that they are included in our global community from the beginning of their academic careers. AGI is creating a global network for geoscience students using social networking and video-sharing websites. Student engagement materials will also address parents' concerns, since they have considerable influence in students' decisions. According to a study by the National Research Center for College and University Admissions, 70 percent of high school juniors say their parents influence their college choices. The AGI Student Engagement Initiative is designed to compliment the recruiting efforts of individual geoscience departments and to assist them in attracting the next generation of geoscientists to our community.

AWG, Enhancing Professional Skills, Providing Resources and Assistance for Women in the Geosciences

NASA Astrophysics Data System (ADS)

Sundermann, C.; Cruse, A. M.; AssociationWomen Geoscientists

2011-12-01

The Association for Women Geoscientists (AWG) was founded in 1977. AWG is an international organization, with ten chapters, devoted to enhancing the quality and level of participation of women in geosciences, and introducing women and girls to geoscience careers. Our diverse interests and expertise cover the entire spectrum of geoscience disciplines and career paths, providing unexcelled networking and mentoring opportunities to develop leadership skills. Our membership is brought together by a common love of earth, atmospheric and ocean sciences, and the desire to ensure rewarding opportunities for women in the geosciences. AWG offers a variety of scholarships, including the Chrysalis scholarship for women who are returning to school after a life-changing interruption, and the Sands and Takken awards for students to make presentations at professional meetings. AWG promotes professional development through workshops, an online bi-monthly newsletter, more timely e-mailed newsletters, field trips, and opportunities to serve in an established professional organization. AWG recognizes the work of outstanding women geoscientists and of outstanding men supporters of women in the geosciences. The AWG Foundation funds ten scholarships, a Distinguished Lecture Program, the Geologist-in-the-Parks program, Science Fair awards, and numerous Girl Scout programs. Each year, AWG sends a contingent to Congressional Visits Day, to help educate lawmakers about the unique challenges that women scientists face in the geoscience workforce.

The role of digital cartographic data in the geosciences

USGS Publications Warehouse

Guptill, S.C.

1983-01-01

The increasing demand of the Nation's natural resource developers for the manipulation, analysis, and display of large quantities of earth-science data has necessitated the use of computers and the building of geoscience information systems. These systems require, in digital form, the spatial data on map products. The basic cartographic data shown on quadrangle maps provide a foundation for the addition of geological and geophysical data. If geoscience information systems are to realize their full potential, large amounts of digital cartographic base data must be available. A major goal of the U.S. Geological Survey is to create, maintain, manage, and distribute a national cartographic and geographic digital database. This unified database will contain numerous categories (hydrography, hypsography, land use, etc.) that, through the use of standardized data-element definitions and formats, can be used easily and flexibly to prepare cartographic products and perform geoscience analysis. ?? 1983.

Citizen-science, Geoethics and Human Niche

NASA Astrophysics Data System (ADS)

Bohle, Martin

2017-04-01

The anthropogenic biogeosphere or 'human niche' is the intersection of the biogeosphere and the sphere of human activities of social, economic, cultural and political nature. The application case for geoethics, namely "appropriate behaviours and practices, wherever human activities interact with the Earth system" [1], is about niche building. Geoethics is about the conduct of people and geoscientists, respectively their ordinary lifestyles and professional activities. Geoscience professionals notice the diverse economic, social and cultural living conditions of people, and the application cases of geosciences mirror the diversity of the global social sphere. Subsequently it is argued: A) when considering the ethical dimensions of global niche building then geosciences should feature 'citizen geoscience'; and B) when considering the functioning of a knowledge-based society under conditions of anthropogenic global change then 'citizen geoscience' facilitates applying that knowledge base. (A) Regarding 'niche building': The design of production systems and consumption patterns embeds geoscience know-how and relates it to the everyday life. Any citizen's activities purposefully interconnect to the biogeosphere for well-being, care-taking, and reproduction, although habitually without involving a geoscientist in professional capacity. In that implicit manner the everyday behaviours and practices of people influence Earth system dynamic. This renders their inherent geoscience know-how a public good as it makes their ignorance a public risk. A comfortable human niche for billions of people requires a global biogeosphere that is disrupted little by citizens' activities and exposes them to hazards that can be tamed. Quite the reverse, anthropogenic global change will disturb living conditions for many citizen. Much geoscience know-how will have to be deployed to tame disturbances in a socially sustainable manner. Sustainability in turn needs involvement of citizens in researching know-how and deploying it, i.e. needs 'citizen geo-scientists' to maintain the human niche. (B) Regarding knowledge-based societies: The rapidly increasing human knowledge base accelerates the scientific-technical revolution. Its industrial-societal implementation confronts societies with numerous change processes. Their speed and scope is a risk as well as the mutual interferences of different change processes that often only get obvious within everyday societal doings. This vigour of change requires robust two-way linkages between research and technological development on one side and societal activities on the other side. Research and development undertaken in cooperation with citizen scientists would improve such linkages, e.g. through increased transparency of research and development or strengthening the sense of belonging of people for their environments. Citizen scientists are a resource, because they are complementary partner to the professional researcher. On one side citizen scientists provide experiences that are rooted in everyday practices and on the other side they facilitate uptake of new practices. Both features are needed in societies that face anthropogenic global change. Summarizing, geoethics affiliates geosciences and 'citizen science' in a particular relationship, i.e. 'citizen geo-science', which is beneficial for knowledge-based societies that are functioning under conditions of anthropogenic global change. [1] http://www.geoethics.org/ (accessed: 8th November 2016) Disclaimer: The views expressed engage the author only, not the employer.

International Convergence on Geoscience Cyberinfrastructure

NASA Astrophysics Data System (ADS)

Allison, M. L.; Atkinson, R.; Arctur, D. K.; Cox, S.; Jackson, I.; Nativi, S.; Wyborn, L. A.

2012-04-01

There is growing international consensus on addressing the challenges to cyber(e)-infrastructure for the geosciences. These challenges include: Creating common standards and protocols; Engaging the vast number of distributed data resources; Establishing practices for recognition of and respect for intellectual property; Developing simple data and resource discovery and access systems; Building mechanisms to encourage development of web service tools and workflows for data analysis; Brokering the diverse disciplinary service buses; Creating sustainable business models for maintenance and evolution of information resources; Integrating the data management life-cycle into the practice of science. Efforts around the world are converging towards de facto creation of an integrated global digital data network for the geosciences based on common standards and protocols for data discovery and access, and a shared vision of distributed, web-based, open source interoperable data access and integration. Commonalities include use of Open Geospatial Consortium (OGC) and ISO specifications and standardized data interchange mechanisms. For multidisciplinarity, mediation, adaptation, and profiling services have been successfully introduced to leverage the geosciences standards which are commonly used by the different geoscience communities -introducing a brokering approach which extends the basic SOA archetype. Principal challenges are less technical than cultural, social, and organizational. Before we can make data interoperable, we must make people interoperable. These challenges are being met by increased coordination of development activities (technical, organizational, social) among leaders and practitioners in national and international efforts across the geosciences to foster commonalities across disparate networks. In doing so, we will 1) leverage and share resources, and developments, 2) facilitate and enhance emerging technical and structural advances, 3) promote interoperability across scientific domains, 4) support the promulgation and institutionalization of agreed-upon standards, protocols, and practice, and 5) enhance knowledge transfer not only across the community, but into the domain sciences, 6) lower existing entry barriers for users and data producers, 7) build on the existing disciplinary infrastructures leveraging their service buses. . All of these objectives are required for establishing a permanent and sustainable cyber(e)-infrastructure for the geosciences. The rationale for this approach is well articulated in the AuScope mission statement: "Many of these problems can only be solved on a national, if not global scale. No single researcher, research institution, discipline or jurisdiction can provide the solutions. We increasingly need to embrace e-Research techniques and use the internet not only to access nationally distributed datasets, instruments and compute infrastructure, but also to build online, 'virtual' communities of globally dispersed researchers." Multidisciplinary interoperability can be successfully pursued by adopting a "system of systems" or a "Network of Networks" philosophy. This approach aims to: (a) supplement but not supplant systems mandates and governance arrangements; (b) keep the existing capacities as autonomous as possible; (c) lower entry barriers; (d) Build incrementally on existing infrastructures (information systems); (e) incorporate heterogeneous resources by introducing distribution and mediation functionalities. This approach has been adopted by the European INSPIRE (Infrastructure for Spatial Information in the European Community) initiative and by the international GEOSS (Global Earth Observation System of Systems) programme.

The Public Acceptance of Biofuels and Bioethanol from Straw- how does this affect Geoscience

NASA Astrophysics Data System (ADS)

Jäger, Alexander; Ortner, Tina; Kahr, Heike

2015-04-01

The Public Acceptance of Biofuels and Bioethanol from Straw- how does this affect Geoscience The successful use of bioethanol as a fuel requires its widespread acceptance by consumers. Due to the planned introduction of a 10 per cent proportion of bioethanol in petrol in Austria, the University of Applied Sciences Upper Austria carried out a representative opinion poll to collect information on the population's acceptance of biofuels. Based on this survey, interviews with important stakeholders were held to discuss the results and collect recommendations on how to increase the information level and acceptance. The results indicate that there is a lack of interest and information about biofuels, especially among young people and women. First generation bioethanol is strongly associated with the waste of food resources, but the acceptance of the second generation, produced from agricultural remnants like straw from wheat or corn, is considerably higher. The interviewees see more transparent, objective and less technical information about biofuels as an essential way to raise the information level and acceptance rate. As the production of bioethanol from straw is now economically feasible, there is one major scientific question to answer: In which way does the withdrawal of straw from the fields affect the formation of humus and, therefore, the quality of the soil? An interdisciplinary approach of researchers in the fields of bioethanol production, geoscience and agriculture in combination with political decision makers are required to make the technologies of renewable bioenergy acceptable to the population.

A Cyber Enabled Collaborative Environment for Creating, Sharing and Using Data and Modeling Driven Curriculum Modules for Hydrology Education

NASA Astrophysics Data System (ADS)

Merwade, V.; Ruddell, B. L.; Fox, S.; Iverson, E. A. R.

2014-12-01

With the access to emerging datasets and computational tools, there is a need to bring these capabilities into hydrology classrooms. However, developing curriculum modules using data and models to augment classroom teaching is hindered by a steep technology learning curve, rapid technology turnover, and lack of an organized community cyberinfrastructure (CI) for the dissemination, publication, and sharing of the latest tools and curriculum material for hydrology and geoscience education. The objective of this project is to overcome some of these limitations by developing a cyber enabled collaborative environment for publishing, sharing and adoption of data and modeling driven curriculum modules in hydrology and geosciences classroom. The CI is based on Carleton College's Science Education Resource Center (SERC) Content Management System. Building on its existing community authoring capabilities the system is being extended to allow assembly of new teaching activities by drawing on a collection of interchangeable building blocks; each of which represents a step in the modeling process. Currently the system hosts more than 30 modules or steps, which can be combined to create multiple learning units. Two specific units: Unit Hydrograph and Rational Method, have been used in undergraduate hydrology class-rooms at Purdue University and Arizona State University. The structure of the CI and the lessons learned from its implementation, including preliminary results from student assessments of learning will be presented.

Creating and maintaining a successful geoscience pathway from 2YC to 4YC for Native Hawaiian Students: First Steps

NASA Astrophysics Data System (ADS)

Guidry, M.; Eschenberg, A.; McCoy, F. W.; McManus, M. A.; Lee, K.; DeLay, J. K.; Taylor, S. V.; Dire, J.; Krupp, D.

2017-12-01

In the Fall of 2015, the two four year (4YC) institutions within the University of Hawaii (UH) system offering baccalaureate degrees in geosciences enrolled only six Native Hawaiian (NH) students out of a total of 194 students in geoscience degree programs. This percentage (3%) of NH students enrolled in geosciences is far lower than the percentage of NH students enrolled at any single institution in the UH system, which ranges from 14 to 42%. At the same time, only six (3%) of the 194 students enrolled in geoscience baccalaureate programs were transfer students from the UH community colleges. Of these six transfer students, three were NH. This reflects the need for increased transfer of NH in the geosciences from two year (2YC) to 4YC. In the Fall of 2015, UH Manoa's (UHM) School of Ocean and Earth Science and Technology (SOEST) accounted for only 0.14% of transfer students from UH community colleges. This compares to 5% in the UHM School of Engineering and 27% in the UHM College of Arts and Sciences. As part of the first year of a multi-institutional five-year NSF TCUP-PAGE (Tribal Colleges and Universities Program - PArtnerships for Geoscience Education) award, we review our first steps and strategies for building a successful and sustainable geoscience transfer pathway for Native Hawaiian and community college students into the three undergraduate geoscience programs (Atmospheric Sciences, Environmental Sciences, and Geology & Geophysics) within SOEST.

Chair Talk: Resources to Maximize Administrative Efforts

NASA Astrophysics Data System (ADS)

MacDonald, H.; Chan, M. A.; Bierly, E. W.; Manduca, C. A.; Ormand, C. J.

2009-12-01

Earth science department chairs are generally scientists who have little/no formal administrative training. The common rotation of faculty members in three-six year cycles distributes the heavy leadership responsibilities but involves little preparation beforehand to deal with budgets, fundraising, personnel issues, confrontations, and crises. The amount of information exchange and support upon exit and handoff to the next chair is variable. Resources for chairs include workshops, meetings (ranging from annual meetings of geoscience chairs to monthly meetings of small groups of chairs from various disciplines on a campus), discussions, and online resources. These resources, some of which we designed in the past several years, provide information and support for chairs, help them share best practices, and reduce time spent “reinventing the wheel”. Most of these resources involve groups of chairs in our discipline who meet together. The AGU Board of Heads and Chairs of Earth and Space Science Departments offers annual one-day workshops at the Fall AGU meeting. The specific topics vary from year to year; they have included goals and roles of heads and chairs, fundraising and Advisory Boards, student recruitment, interdisciplinarity, dual-career couples, and undergraduate research. The workshop provides ample opportunities for open discussion. Annual one-two day meetings of groups of geoscience department chairs (e.g., research universities in a particular region) provide an opportunity for chairs to share specific data about their departments (e.g., salaries, graduate student stipends, information about facilities) and discuss strategies. At the College of William and Mary, a small group of chairs meets monthly throughout the year; each session includes time for open discussion as well as a more structured discussion on a particular topic (e.g., merit review, development and fundraising, mentoring early career faculty and the tenure process, leadership styles, dealing with difficult situations, working with alumni). Through the Association for Women Geoscientists, we have offered annual one-hour lunch discussions at AGU and GSA meetings on issues facing women chairs and deans. Focusing on a different topic each year, these discussions include sharing good solutions, problem solving on various case scenarios, and so forth. In addition, the Building Strong Geoscience Departments program has offered workshops on different aspects of building strong geoscience departments, distributed reports, and made a variety of materials that would be useful to geoscience chairs available on their website. These programs and resources should continue and build to provide more continuity within departments and to increase a broader experience base of faculty. One of the greatest resources for chairs is to have personal connections with other chairs (via these programs), who can be called upon for advice, ideas, or general support. The sense of collective community could act in a powerful way to inspire and encourage more innovations and creative solutions to promote stronger departments.

Offering a Geoscience Professional Development Program to Promote Science Education and Provide Hands-on Experiences for K-12 Science Educators

ERIC Educational Resources Information Center

Fakayode, Sayo O.; Pollard, David A.; Snipes, Vincent T.; Atkinson, Alvin

2014-01-01

Development of an effective strategy for promoting science education and professional development of K-12 science educators is a national priority to strengthen the quality of science, technology, engineering, and mathematics (STEM) education. This article reports the outcomes of a Geoscience Professional Development Program (GPDP) workshop…

Integrating Geoscience and Sustainability: Examining Socio-Techno-Ecological Relationships within Content Designed to Prepare Teachers

ERIC Educational Resources Information Center

Hale, Annie E.; Shelton, Catharyn C.; Richter, Jennifer; Archambault, Leanna M.

2017-01-01

Coupling the study of sustainability with geoscience may enable students to explore science in a more sophisticated way by examining the social-technological-ecological relationships that exist between human-nonhuman and flora-fauna-land interactions. Elementary educators are a population capable of making these issues come to life for today's…

Supporting Success for All Students

NASA Astrophysics Data System (ADS)

Manduca, C. A.; Macdonald, H.; McDaris, J. R.; Weissmann, G. S.

2015-12-01

The geoscience student population in the United States today does not reflect the diversity of the US population. Not only does this challenge our ability to educate sufficient numbers of students in the geosciences, it also challenges our ability to address issues of environmental justice, to bring geoscience expertise to diverse communities, and to pursue a research agenda reflecting the needs and interests of our nation as a whole. Programs that are successful in supporting students from underrepresented groups attend to the whole student (Jolly et al, 2004) as they develop not only knowledge and skills, but a sense of belonging and a drive to succeed in geoscience. The whole student approach provides a framework for supporting the success of all students, be they members of underrepresented groups or not. Important aspects of support include mentoring and advising, academic support, an inclusive learning community, and opportunities to learn about the profession and to develop geoscience and professional skills. To successfully provide support for the full range of students, it is critical to consider not only what opportunities are available but the barriers different types of students face in accessing these opportunities. Barriers may arise from gaps in academic experiences, crossing into a new and unfamiliar culture, lack of confidence, stereotype threat, implicit bias and other sources. Isolation of geoscience learning from its application and social context may preferentially discourage some groups. Action can be taken to increase support for all students within an individual course, a department or an institution. The InTeGrate STEP Center for the Geosciences, the Supporting and Advancing Geoscience Education at Two-Year Colleges program and the On the Cutting Edge Professional Development for Geoscience Faculty program all provide resources for individuals and departments including on line information, program descriptions, and workshop opportunities.

Leveraging Earth and Planetary Datasets to Support Student Investigations in an Introductory Geoscience Course

NASA Astrophysics Data System (ADS)

Ryan, Jeffrey; De Paor, Declan

2016-04-01

Engaging undergraduates in discovery-based research during their first two years of college was a listed priority in the 2012 Report of the USA President's Council of Advisors on Science and Technology (PCAST), and has been the focus of events and publications sponsored by the National Academies (NAS, 2015). Challenges faced in moving undergraduate courses and curricula in this direction are the paired questions of how to effectively provide such experiences to large numbers of students, and how to do so in ways that are cost- and time-effiicient for institutions and instructional faculty. In the geosciences, free access to of a growing number of global earth and planetary data resources and associated visualization tools permits one to build into introductory-level courses straightforward data interrogation and analysis activities that provide students with valuable experiences with the compilation and critical investigation of earth and planetary data. Google Earth provides global Earth and planetary imagery databases that span large ranges in resolution and in time, permitting easy examination of earth surface features and surface features on Mars or the Moon. As well, "community" data sources (i.e., Gigapan photographic collections and 3D visualizations of geologic features, as are supported by the NSF GEODE project) allow for intensive interrogation of specific geologic phenomena. Google Earth Engine provides access to rich satellite-based earth observation data, supporting studies of weather and related student efforts. GeoMapApp, the freely available visualization tool of the Interdisciplinary Earth Data Alliance (IEDA), permits examination of the seafloor and the integration of a range of third-party data. The "Earth" meteorological website (earth.nullschool.net) provides near real-time visualization of global weather and oceanic conditions, which in combination with weather option data from Google Earth permits a deeper interrogation of atmospheric conditions. In combination, these freely accessible data resources permit one to transform general- audience geoscience courses into extended investigations, in which students discover key information about the workings of our planet.

Developing Geoscience Students' Quantitative Skills

NASA Astrophysics Data System (ADS)

Manduca, C. A.; Hancock, G. S.

2005-12-01

Sophisticated quantitative skills are an essential tool for the professional geoscientist. While students learn many of these sophisticated skills in graduate school, it is increasingly important that they have a strong grounding in quantitative geoscience as undergraduates. Faculty have developed many strong approaches to teaching these skills in a wide variety of geoscience courses. A workshop in June 2005 brought together eight faculty teaching surface processes and climate change to discuss and refine activities they use and to publish them on the Teaching Quantitative Skills in the Geosciences website (serc.Carleton.edu/quantskills) for broader use. Workshop participants in consultation with two mathematics faculty who have expertise in math education developed six review criteria to guide discussion: 1) Are the quantitative and geologic goals central and important? (e.g. problem solving, mastery of important skill, modeling, relating theory to observation); 2) Does the activity lead to better problem solving? 3) Are the quantitative skills integrated with geoscience concepts in a way that makes sense for the learning environment and supports learning both quantitative skills and geoscience? 4) Does the methodology support learning? (e.g. motivate and engage students; use multiple representations, incorporate reflection, discussion and synthesis) 5) Are the materials complete and helpful to students? 6) How well has the activity worked when used? Workshop participants found that reviewing each others activities was very productive because they thought about new ways to teach and the experience of reviewing helped them think about their own activity from a different point of view. The review criteria focused their thinking about the activity and would be equally helpful in the design of a new activity. We invite a broad international discussion of the criteria(serc.Carleton.edu/quantskills/workshop05/review.html).The Teaching activities can be found on the Teaching Quantitative Skills in the Geosciences website (serc.Carleton.edu/quantskills/). In addition to the teaching activity collection (85 activites), this site contains a variety of resources to assist faculty with the methods they use to teach quantitative skills at both the introductory and advanced levels; information about broader efforts in quantitative literacy involving other science disciplines, and a special section of resources for students who are struggling with their quantitative skills. The site is part of the Digital Library for Earth Science Education and has been developed by geoscience faculty in collaboration with mathematicians and mathematics educators with funding from the National Science Foundation.

The Quantitative Preparation of Future Geoscience Graduate Students

NASA Astrophysics Data System (ADS)

Manduca, C. A.; Hancock, G. S.

2006-12-01

Modern geoscience is a highly quantitative science. In February, a small group of faculty and graduate students from across the country met to discuss the quantitative preparation of geoscience majors for graduate school. The group included ten faculty supervising graduate students in quantitative areas spanning the earth, atmosphere, and ocean sciences; five current graduate students in these areas; and five faculty teaching undergraduate students in the spectrum of institutions preparing students for graduate work. Discussion focused in four key ares: Are incoming graduate students adequately prepared for the quantitative aspects of graduate geoscience programs? What are the essential quantitative skills are that are required for success in graduate school? What are perceived as the important courses to prepare students for the quantitative aspects of graduate school? What programs/resources would be valuable in helping faculty/departments improve the quantitative preparation of students? The participants concluded that strengthening the quantitative preparation of undergraduate geoscience majors would increase their opportunities in graduate school. While specifics differed amongst disciplines, a special importance was placed on developing the ability to use quantitative skills to solve geoscience problems. This requires the ability to pose problems so they can be addressed quantitatively, understand the relationship between quantitative concepts and physical representations, visualize mathematics, test the reasonableness of quantitative results, creatively move forward from existing models/techniques/approaches, and move between quantitative and verbal descriptions. A list of important quantitative competencies desirable in incoming graduate students includes mechanical skills in basic mathematics, functions, multi-variate analysis, statistics and calculus, as well as skills in logical analysis and the ability to learn independently in quantitative ways. Calculus, calculus-based physics, chemistry, statistics, programming and linear algebra were viewed as important course preparation for a successful graduate experience. A set of recommendations for departments and for new community resources includes ideas for infusing quantitative reasoning throughout the undergraduate experience and mechanisms for learning from successful experiments in both geoscience and mathematics. A full list of participants, summaries of the meeting discussion and recommendations are available at http://serc.carleton.edu/quantskills/winter06/index.html. These documents, crafted by a small but diverse group can serve as a starting point for broader community discussion of the quantitative preparation of future geoscience graduate students.

A Collaborative Effort to Build a Modular Course on GeoEthics

NASA Astrophysics Data System (ADS)

Cronin, V. S.; Di Capua, G.; Palinkas, C. M.; Pappas Maenz, C.; Peppoloni, S.; Ryan, A. M.

2014-12-01

The need to promote ethical practice in the geosciences has long been recognized. Governmental boards for licensing professional geoscientists commonly require participation in continuing-education courses or workshops about professional ethics as part of the license-renewal processes. Geoscience-based companies and organizations of professional geoscientists have developed ethical codes for their members or employees. Ethical problems have been reported that involve the practice of science applied to Earth studies, interpersonal relationships within geoscience departments, business practices in geoscience-based companies, field work and the destructive modification of geologic sites, public policy development or implementation related to Earth resources, extractive resource industries, development that modifies landscapes in significant ways, interactions with the press and other media professionals, and even interactions with individuals or groups that have a significantly different worldview. We are working toward the creation of a modular semester-long course in GeoEthics. The modules will be free-standing, so each could be repurposed for use in a different course; however, the GeoEthics course will provide a useful overall introduction to a variety of topics in ethics applied in the context of geoscience. Such a course might be an excellent capstone course for undergraduate geoscientists, or an introductory course for graduate students. The first module will cover basics intended to provide a common vocabulary of words, ideas and practices that will be used throughout the course. The remaining 5-6 modules will focus on aspects of geoscience in which ethical considerations play an important role. We feel that the geoscience classroom can provide a safe, controlled environment in which students can confront a representative sample of the types of ethical issues they might encounter in their professional or academic careers. Our goal is to help students develop effective strategies for working through these dilemmas. Our modules will utilize formal discussion, role-playing, debate, and reflective writing, among other techniques. We hope that this will lead students to internalize these lessons so that they lead careers in which ethical practice is an essential element.

A collaborative effort to build a modular course on Geoethics

NASA Astrophysics Data System (ADS)

Cronin, Vincent; Di Capua, Giuseppe; Palinkas, Cindy; Pappas Maenz, Catherine; Peppoloni, Silvia; Ryan, Anne-Marie

2015-04-01

The need to promote ethical practice in the geosciences has long been recognized. Governmental boards for licensing professional geoscientists commonly require participation in continuing-education courses or workshops about professional ethics as part of the license-renewal processes. Geoscience-based companies and organizations of professional geoscientists have developed ethical codes for their members or employees. Ethical problems have been reported that involve the practice of science applied to Earth studies, interpersonal relationships within geoscience departments, business practices in geoscience-based companies, field work and the destructive modification of geologic sites, public policy development or implementation related to Earth resources, extractive resource industries, development that modifies landscapes in significant ways, interactions with the press and other media professionals, and even interactions with individuals or groups that have a significantly different worldview. We are working toward the creation of a modular semester-long course in Geoethics. The modules will be free-standing, so each could be repurposed for use in a different course; however, the Geoethics course will provide an useful overall introduction to a variety of topics in ethics applied in the context of geoscience. Such a course might be an excellent capstone course for undergraduate geoscientists, or an introductory course for graduate students. The first module will cover basics intended to provide a common vocabulary of words, ideas and practices that will be used throughout the course. The remaining 5-6 modules will focus on aspects of geoscience in which ethical considerations play an important role. We feel that the geoscience classroom can provide a safe, controlled environment in which students can confront a representative sample of the types of ethical issues they might encounter in their professional or academic careers. Our goal is to help students develop effective strategies for working through these dilemmas. Our modules will utilize formal discussion, role-playing, debate, and reflective writing, among other techniques. We hope that this will lead students to internalize these lessons so that they lead careers in which ethical practice is an essential element.

Teaching with Games: Online Resources and Examples for Entry Level Courses

NASA Astrophysics Data System (ADS)

Teed, R.; Manduca, C.

2004-12-01

Using games to teach introductory geoscience can motivate students to enthusiastically learn material that they might otherwise condemn as "boring". A good educational game is one that immerses the players in the material and engages them for as long as it takes to master that material. There are some good geoscience games already available, but instructors can also create their own, suitable to their students and the content that they are teaching. Game-Based Learning is a module on the Starting Point website for faculty teaching entry level geosciences. It assists faculty in using games in their teaching by providing a description of the features of game-based learning, why you would use it, how to use games to teach geoscience, examples, and references. Other issues discussed include the development of video games for teaching, having your students create educational games, what makes a good game, handling competition in the classroom, and grading. The examples include descriptions of and rules for a GPS treasure hunt, a geology quiz show, and an earthquake game, as well as links to several online geological video games, and advice on how to design a paleontology board game. Starting Point is intended to help both experienced faculty and new instructors meet the challenge of teaching introductory geoscience classes, including environmental science and oceanography as well as more traditional geology classes. For many students, these classes are both the first and the last college-level science class that they will ever take. They need to learn enough about the Earth in that one class to sustain them for many decades as voters, consumers, and sometimes even as teachers. Starting Point is produced by a group of authors working with the Science Education Resource Center. It contains dozens of detailed examples categorized by geoscience topic with advice about using them and assessing learning. Each example is linked to one of many modules, such as Game-Based Learning, Interactive Lectures, or Using an Earth History Approach. These modules describe teaching tools and techniques, provide examples and advice about using them in an introductory geoscience class, and give instructors details on how to create their own exercises.

Career Paths for Geosciences Students (Invited)

NASA Astrophysics Data System (ADS)

Bowers, T. S.; Flewelling, S. A.

2013-12-01

Current and future drivers of hiring in the geosciences include climate, environment, energy, georisk and litigation areas. Although climate is closely linked to the atmospheric sciences, hiring needs in the geosciences exist as well, in understanding potential impacts of climate change on coastal erosion and water resources. Where and how to consider carbon sequestration as a climate mitigation policy will also require geosciences expertise. The environmental sciences have long been a source of geosciences hiring, and have ongoing needs in the areas of investigation of contamination, and in fluid and chemical transport. The recent expansion of the energy sector in the U.S. is providing opportunities for the geosciences in oil and gas production, hydraulic fracturing, and in geothermal development. In georisk, expertise in earthquake and volcanic hazard prediction are increasingly important, particularly in population centers. Induced seismicity is a relatively new area of georisk that will also require geosciences skills. The skills needed in the future geosciences workforce are increasingly interdisciplinary, and include those that are both observational and quantitative. Field observations and their interpretation must be focused forward as well as backwards and include the ability to recognize change as it occurs. Areas of demand for quantitative skills include hydrological, geophysical, and geochemical modeling, math and statistics, with specialties such as rock mechanics becoming an increasingly important area. Characteristics that students should have to become successful employees in these sectors include strong communication skills, both oral and written, the ability to know when to stop "studying" and identify next steps, and the ability to turn research areas into solutions to problems.

Broadening Awareness and Participation in the Geosciences Among Underrepresented Minorities in STEM

NASA Astrophysics Data System (ADS)

Blake, R.; Liou-Mark, J.

2012-12-01

An acute STEM crisis exists nationally, and the problem is even more dire among the geosciences. Since about the middle of the last century, fewer undergraduate and graduate degrees have been granted in the geosciences than in any other STEM fields. To help in ameliorating this geoscience plight, particularly from among members of racial and ethnic groups that are underrepresented in STEM fields, the New York City College of Technology (City Tech) launched a vibrant geoscience program and convened a community of STEM students who are interested in learning about the geosciences. This program creates and introduces geoscience knowledge and opportunities to a diverse undergraduate student population that was never before exposed to geoscience courses at City Tech. This geoscience project is funded by the NSF OEDG program, and it brings awareness, knowledge, and geoscience opportunities to City Tech's students in a variety of ways. Firstly, two new geoscience courses have been created and introduced. One course is on Environmental Remote Sensing, and the other course is an Introduction to the Physics of Natural Disasters. The Remote Sensing course highlights the physical and mathematical principles underlying remote sensing techniques. It covers the radiative transfer equation, atmospheric sounding techniques, interferometric and lidar systems, and an introduction to image processing. Guest lecturers are invited to present their expertise on various geoscience topics. These sessions are open to all City Tech students, not just to those students who enroll in the course. The Introduction to the Physics of Natural Disasters course is expected to be offered in Spring 2013. This highly relevant, fundamental course will be open to all students, especially to non-science majors. The course focuses on natural disasters, the processes that control them, and their devastating impacts to human life and structures. Students will be introduced to the nature, causes, risks, effects, and prediction of natural disasters including earthquakes, volcanoes, tsunamis, landslides, subsidence, global climate change, severe weather, coastal erosion, floods, mass extinctions, wildfires, and meteoroid impacts. In addition to the brand new geoscience course offerings, City Tech students participate in geoscience - seminars, guest lectures, lecture series, and geoscience internship and fellowship workshops. The students also participate in geoscience exposure trips to NASA/GISS Columbia University, NOAA-CREST, and the Brookhaven National Laboratory. Moreover, the undergrads are provided opportunities for paid research internships via two NSF grants - NSF REU and NSF STEP. Geoscience projects are also integrated into course work, and students make geoscience group project presentations in class. Students also participate in geoscience career and graduate school workshops. The program also creates geoscience articulation agreements with the City College of New York so that students at City Tech may pursue Bachelor's and advanced degrees in the geosciences. This program is supported by NSF OEDG grant #1108281.

Tribal and Indigenous Geoscience and Earth System Science: Ensuring the Evolution and Practice of Underrepresented Scientists and Researchers in the 21ST Century and Beyond

NASA Astrophysics Data System (ADS)

Bolman, J.

2014-12-01

The time is critical for Tribal, Indigenous and Underrepresented K-12/university students and communities to accept the duty to provide representation in Earth System Sciences/Geosciences fields of study and professions. Tribal nations in the U.S have a unique legal status rooted in a complex relationship between the U.S. federal government, individual state/local governments and Tribal authorities. Although geosciences are often at the center of these relationships, especially as they pertain to the development of natural resources, tribal economics, and environmental stewardship, Tribal/Indigenous people remain severely underrepresented in advanced geoscience education. Our students and communities have responded to the invitation. To represent and most important develop and lead research initiatives. Leadership is a central focus of the invitation to participate, as Tribal people have immense responsibility for significant landscapes across North American Continent, critical natural resources and millennia of unpretentious natural evolution with the localized native geologies, species and environmental systems. INRSEP and Pacific Northwest Tribal Nations found sustaining relationships with the Geoscience Alliance, MS PHD's, Woods Hole PEP, Native American Pacific Islander Research Experience (NAPIRE) and LSAMP programs, in addition to state/federal agencies, has advanced culturally-relevant STEM research. Research foundationally grounded on traditional ecological knowledge, individual and Tribal self-determination. A key component is student research experiences within their ancestral homelands and traversing to REU's in multiple national and international Tribal/Indigenous ancestral territories. The relationships also serve an immense capacity in tracking student achievement, promoting best practices in research development and assessing outcomes. The model has significantly improved the success of students completing STEM graduate programs. The presentation will highlight lessons learned on how to 1) Ensure a diverse cohort/community of student, professionals and researchers; 2) Evolve intergenerational mentoring processes/outcomes; 3) Innovate research and programs; and 4) Advance the broader impact of geosciences research and outcomes.

Developing Expert Interdisciplinary Thinkers: Online Resources for Preparing Pre-service Teachers to Teach the NGSS

NASA Astrophysics Data System (ADS)

Kent, M.; Egger, A. E.; Bruckner, M. Z.; Manduca, C. A.

2014-12-01

Over 100,000 students obtain a bachelor's degree in education every year; these students most commonly encounter the geosciences through a general education course, and it may be the only geoscience course they ever take. However, the Next Generation Science Standards (NGSS) contain much more Earth science content than previous standards. In addition, the NGSS emphasize the use of science and engineering practices in the K-12 classroom. Future teachers need to experience learning science as a scientist, through a hands-on, activity-based learning process, in order to give them the skills they need to teach science that same way in the future. In order to be successful at teaching the NGSS, both current and future teachers will need more than a single course in geoscience or science methods. As a result, there is now a key opportunity for geoscience programs to play a vital role in strengthening teacher preparation programs, both through introductory courses and beyond. To help programs and individual faculty take advantage of this opportunity, we have developed a set of web-based resources, informed by participants in the InTeGrate program as well as by faculty in exemplary teacher preparation programs. The pages address the program-level task of creating engaging and effective courses for teacher preparation programs, with the goal of introducing education majors to the active pedagogies and geoscience methods they will later use in their own classrooms. A collection of exemplary Teacher Preparation programs is also included. Additional pages provide information on what it means to be an "expert thinker" in the geosciences and how individual faculty and teachers can explicitly teach these valuable skills that are reflected in the science and engineering practices of the NGSS. Learn more on the InTeGrate web site about preparing future teachers: serc.carleton.edu/integrate/programs/teacher_prep.htmland training expert thinkers: serc.carleton.edu/integrate/teaching_materials/expert_thinkers.html

Connecting GEON: Making sense of the myriad resources, researchers and concepts that comprise a geoscience cyberinfrastructure

NASA Astrophysics Data System (ADS)

Gahegan, Mark; Luo, Junyan; Weaver, Stephen D.; Pike, William; Banchuen, Tawan

2009-04-01

Simply placing electronic geoscience resources such as datasets, methods, ontologies, workflows and articles in a digital library or cyberinfrastructure does not mean that they will be used successfully by other researchers or educators. It is also necessary to provide the means to locate potentially useful content, and to understand it. Without suitable provision for these needs, many useful resources will go undiscovered, or else will be found but used inappropriately. In this article, we describe an approach to discovering, describing and understanding e-resources based on the notion that meaning is carried in the interconnections between resources and the actors in the cyberinfrastructure (including individuals, groups, organizations), as well as by ontologies and conventional metadata. Navigation around this universe is achieved by implementing the idea of perspectives as dynamic, conceptual views (defined by SPARQL-like queries against an OWL schema) that not only act as filters, but also dynamically promote and demote concepts, relationships and properties according to their immediate relevance. We describe a means to represent a wide variety of interactions between resources using the notion of a knowledge nexus, and we illustrate its use with resources and actors from the Geosciences Network (GEON) cyberinfrastructure community. We also closely link browsing and visualizing strategies to our nexus, drawing on ideas from semiotics to move resources and connections not currently of interest from the foreground to the background, and vice versa, using a new form of adaptive perspective. We illustrate our ideas via ConceptVista, an open-source concept mapping application that provides rich, visual depictions of the resources, cyber-community and myriad connections between them. Examples are presented that show how geoscientific knowledge can be explored not only via ontological structure, but also by use cases, social networks, citation graphs and organization charts; all of which may carry some aspects of meaning for the user.

Be Explicit: Geoscience Program Design to Prepare the Next Generation of Geoscientists

NASA Astrophysics Data System (ADS)

Mogk, D. W.

2015-12-01

The work of geoscientists is to engage inquiry, discovery and exploration of Earth history and processes, and increasingly, to apply this knowledge to the "grand challenges" that face humanity. Geoscience as a discipline is confronted with an incomplete geologic record, observations or data that are often ambiguous or uncertain, and a need to grasp abstract concepts such as temporal reasoning ('deep time'), spatial reasoning over many orders of magnitude, and complex system behavior. These factors provide challenges, and also opportunities, for training future geoscientists. Beyond disciplinary knowledge, it is also important to provide opportunities for students to engage the community of practice and demonstrate how to "be" a geoscientist. Inculcation of geoscience "ways of knowing" is a collective responsibility for geoscientists (teaching faculty and other professionals), at all instructional levels, in all geoscience disciplines, and for all students. A whole-student approach is recommended. Geoscience programs can be designed to focus on student success by explictly: 1) defining programmatic student learning outcomes , 2) embedding assessments throughout the program to demonstrate mastery, 3) aligning course sequences to reinforce and anticipate essential concepts/skills, 4) preparing students to be life-long learners; 5) assigning responsibilities to courses/faculty to ensure these goals have been met; 6) providing opportunities for students to "do" geoscience (research experiences), and 7) modeling professional behaviors in class, field, labs, and informal settings. Extracurricular departmental activities also contribute to student development such as journal clubs, colloquia, field trips, and internships. Successful design of geoscience department programs is informed by: the AGI Workforce program and Summit on the Future of Geoscience Education that define pathways for becoming a successful geoscientist; training in Geoethics; Geoscience Education Research; and the NAGT Building Strong Departments program that has developed extensive web-based resources using the "matrix approach" http://nagt.org/nagt/profdev/twp/trav_departments.html. Geoscience departments should commit to producing great Science and great Scientists.

Engaging secondary students in geoscience investigations through the use of low-cost instrumentation

NASA Astrophysics Data System (ADS)

Dunn, A. L.; Hansen, W.; Healy, S.

2010-12-01

Many of the future challenges facing the United States, such as climate change, securing energy resources, soil degradation, water resources, and atmospheric pollution, are part of the domain of geosciences. Currently, our colleges and universities are not graduating enough geoscience majors to meet this demand, with only 0.27% of all bachelor's degrees granted in geoscience fields in 2006, the fewest in any scientific field (NSF 2008). Moreover, undergraduate recruitment in geosciences from traditionally underrepresented groups is significantly poorer than other STEM fields, with underrepresented groups comprising just 5% of total geoscience bachelor’s degrees awarded (Czujko 2004). Undergraduate geoscience programs therefore have a critical need to not just grow in size, but to expand the spectrum of students within their programs to better reflect the country’s diversity. In 2009, Worcester State College (WSC) initiated an effort as part of NSF's Opportunities for Enhancing Diversity in the Geosciences Program to address this problem on a local scale. Through this program, we are creating a pipeline for diversity in the geosciences through a multi-faceted approach involving teacher training, high school internships, and a co-enrollment and scholarship program between Worcester Public Schools and WSC. Worcester, Massachusetts has a median household income of 43,779, 13,902 below the median household income for Massachusetts, and 24% of the city’s children live below the poverty line. Worcester is a diverse city: 19% of the population is Latino, 9% African-American, and 7% Asian-American, with over 18% foreign-born residents. This diversity is reflected in the city’s school system, where over 80 languages are spoken. In July 2010, the program was initiated with a week-long teacher training workshop. The participants were middle and high school science teachers from Worcester and the surrounding area. The workshop focused on issues of sustainability related to the geosciences, such as solar and wind power, water and soil quality, and assessing land-use change through remote sensing and geospatial tools. The goal of the workshop was to give the teachers tools to engage students in investigating these concepts in the classroom, thereby stimulating an interest in geosciences that would carry over into undergraduate education. As part of the workshop, we provided a low-cost set of tools to give to the teachers for hands-on use in the classroom. We developed a compact, rugged system for measuring solar insolation and temperature, and combined it with a datalogger to collect a continuous timeseries of data. We also built a standalone anemometer for measuring wind speed. These instruments offer entry points for multiple types of classroom investigations into weather, climate, and renewable energy potential. They also provide a platform for practicing mathematical and computer skills such as timeseries graphing, data analysis, spreadsheet use, etc. The cost of the pyranometer, datalogger, and anemometer setup was $229 per user. Feedback from workshop participants was very positive, and the teachers were confident that the instrumentation would give them a new way to engage students in geoscience topics.

Inclusion and Access for Students with Disabilties in Geoscience Field Learning Environments

NASA Astrophysics Data System (ADS)

Marshall, A. M.

2017-12-01

In the modern age of technology, physical ability is no longer a requirement for a successful career as a geoscientist. Yet students who do not fit the traditional physical image of a geologist are often excluded from the discipline. Individuals with disabilities - who make up a percentage of every ethnicity, age group and gender - often face great difficulty when working towards a geoscience degree. There are substantial physical barriers to participation in traditional lab and field environments and significant social barriers from deeply held cultural bias within the geoscience community from those who assume a fully able body is a requisite to a geoscience career. With intentional planning and the thoughtful use of technological aids, physical barriers to participation can be addressed in such a way as to provide engaging and inclusive learning opportunities for students of all physical abilities. The social barrier, perhaps the more challenging to address, can only be dismantled by faculty and staff who are willing to model inclusive practices and promote a culture that focuses less on a student's ability to `hike like a geologist', and more on an individual's ability to `think like a geologist'.

Use of The Math You Need When You Need It website outside of introductory geoscience courses

NASA Astrophysics Data System (ADS)

Baer, E. M.; Wenner, J. M.

2011-12-01

Web usage statistics and a recent survey of visitors to The Math You Need, When You Need It (TMYN) suggest that these web resources serve a significant number of students beyond those for whom they were originally intended. The web-based modules of TMYN are asynchronous online resources designed to help undergraduates learn quantitative concepts essential in a concurrent introductory geoscience course. In the past year, approximately 1,000 students accessed TMYN through associated geoscience courses; however, in that same time period,more than 40 times that number interacted significantly with the site according to Google Analytics. Of the nearly 220,000 total visitors, ~15% stayed on the site for longer than one minute and ~20% visited two or more pages within the site, suggesting that the content is engaging and useful to many of the visitors. In a pop-up survey of users, 81% of the nearly 350 respondents reported that they found what they were looking for. Although the nature of TMYN website users is difficult to discern definitively, daily, weekly and monthly use patterns indicate a predominance of academic users. Access to the site is lowest during the summer months and on Friday and Saturday, and is elevated on Sunday through Thursdays. Furthermore, in a pop-up survey of users who accessed more than one page, greater than half (56%) of the 346 respondents were students, 20% collegiate faculty and 9% K-12 teachers. Although the resources are specifically designed for geoscience students, 61% of survey respondents identified themselves as associated with other STEM disciplines. Thus, despite the decidedly geoscientific slant to these resources, survey data suggest that many STEM students and teachers are searching for the kinds of topics covered by TMYN. Furthermore, web use statistics indicate a substantial need for high quality web-based quantitative skill support materials for all STEM disciplines.

Teach the Earth: On-line Resources for Teachers and Teachers of Teachers

NASA Astrophysics Data System (ADS)

Manduca, C. A.

2007-12-01

Effective Earth science education depends on excellent teachers: teachers who not only possess a strong grasp of geoscience but are also well-versed in the pedagogic methods they need to connect with their audience. Preparing Earth science teachers is a task no less challenging that also requires strengths in both areas. The Teach the Earth website provides a variety of resources to support preparation of Earth science teachers. Here you can find collections of teaching activities addressing all aspects of the Earth system; discussions of teaching methods linked to examples of their use in geoscience courses; and the Earth Exploration Toolbook, a resource specifically designed for teachers who would like to incorporate data rich activities in their teaching. These resources are suitable for use by teachers, students in courses addressing the methodology of teaching Earth science and science, and faculty designing courses. Faculty working with current and future teachers will find a section on Preparing Teachers to Teach Earth Science with a collection of courses designed specifically to benefit future Earth Science teachers, examples of key activities in these courses, and descriptions of programs for pre-service and in-service teachers. The materials housed in this web-resource demonstrate a wide range of fruitful approaches and exciting opportunities. On the order of 25,000 individuals use the site repeatedly during the year. We estimate that 27 percent of these users are geoscience faculty and 12 percent are teachers. We invite teachers, faculty, researchers, and educators to enhance this resource by contributing descriptions of activities, courses, or programs as a mechanism for sharing their experience with others engaged in similar work.

Contributions to Public Understanding of Science by the Lamont-Doherty Earth Observatory (II): Web-Based Projects for Teachers and Students

NASA Astrophysics Data System (ADS)

Passow, M. J.; Kastens, K. A.; Goodwillie, A. M.; Brenner, C.

2009-12-01

The Lamont-Doherty Earth Observatory of Columbia University (LDEO) continues its long history of contributions to public understanding of Science. Highlights of current efforts are described in paired posters. Part 2 focuses on web-based activities that foster access to LDEO cutting-edge research for worldwide audiences. “Geoscience Data Puzzles" are activities that purposefully present a high ratio of insight-to-effort for students. Each Puzzle uses selected authentic data to illuminate fundamental Earth processes typically taught in Earth Science curricula. Data may be in the form of a graph, table, map, image or combination of the above. Some Puzzles involve downloading a simple Excel file, but most can be worked from paper copies. Questions guide students through the process of data interpretion. Most Puzzles involve calculations, with emphasis on the too-seldom-taught skill of figuring out what math process is useful to answer an unfamiliar question or solve a problem. Every Puzzle offers "Aha" insights, when the connection between data and process or data and problem comes clear in a rewarding burst of illumination. Time needed to solve a Puzzle is between 15 minutes and an hour. “GeoMapApp” is a free, map-based data exploration and visualization application from the LDEO Marine Geoscience Data System group. GeoMapApp provides direct access to hundreds of data sets useful to geoscience educators, including continuously-updated Global Multi-Resolution Topography compilations that incorporates high-resolution bathymetry in the oceans and Space Shuttle elevations over land. A new User Guide, multi-media tutorials and webinar offer follow-along help and examples. “Virtual Ocean” integrates GeoMapApp functionality with NASA World Wind code to provide a powerful new 3-D platform for interdisciplinary geoscience research and education. Both GeoMapApp and Virtual Ocean foster scientific understanding and provide training in new data visualization technologies. LDEO scientists have contributed to the extensive collection of education resources developed by the Consortium for Ocean Leadership’s Deep Earth Academy). As part of the international research effort to interpret Earth's history by retrieving seafloor samples and monitoring subseafloor environments, LDEO's Borehole Research Group deploys downhole tools to acquire a wide variety of situ geophysical measurements. LDEO scientists contribute significantly to the web portal that facilitates communication between the drillship and the public. It features blogs, games, a graphic novel, teacher resources, and integration with Facebook and Twitter social networking sites Participants in LDEO's monthly "Earth2Class Workshops for Teachers" have created one of the most extensive collections of resources available in Earth Science education. These include curriculum units; teacher-developed lessons, activities, and power points; peer-provided tips for effective teaching; review guides to help prepare for standardized tests; selected web links, and more. Thousands of teachers and students around the world access these LDEO-developed resources every month during the school year.

Effective Recruiting and Intrusive Retention Strategies for Diversifying the Geosciences through a Research Experiences for Undergraduate Program

NASA Astrophysics Data System (ADS)

Liou-Mark, J.; Blake, R.; Norouzi, H.; Yuen-Lau, L.; Ikramova, M.

2016-12-01

Worse than in most Science, Technology, Engineering, and Mathematics (STEM) fields, underrepresented minority (URM) groups in the geosciences are reported to be farthest beneath the national benchmarks. Even more alarming, the geosciences have the lowest diversity of all the STEM disciplines at all three levels of higher education. In order to increase the number of underrepresented groups in the geosciences, a National Science Foundation funded Research Experiences for Undergraduates (REU) program at the New York City College of Technology has implemented effective recruitment strategies to attract and retain diverse student cohorts. Recruitment efforts include: 1) establishing partnership with the local community colleges; 2) forging collaborations with scientists of color; 3) reaching out to the geoscience departments; and 4) forming relationships with STEM organizations. Unlike the other REU programs which primarily provide a summer-only research experience, this REU program engages students in a year-long research experience. Students begin their research in the summer for nine weeks, and they continue their research one day a week in the fall and spring semesters. During the academic year, they present their projects at conferences. They also serve as STEM ambassadors to community and high school outreach events. This one-year triad connection of 1) professional organizations/conferences, 2) continual research experience, and 3) service constituent has resulted in higher retention and graduation rates of URMs in the STEM disciplines. Both formative and summative program assessment have uncovered and shown that strong recruitment efforts accompanied by intrusive retention strategies are essential to: a) sustain and support STEM URMs in developing confidence as scientists; b) create formal and informal STEM communities; and c) provide a clear pathway to advanced degrees and to the geoscience workforce. This project is supported by NSF REU Grant #1560050.

Teaching Mineralogy, Petrology and Geochemistry in the 21st Century: Instructional Resources for Geoscience Faculty

NASA Astrophysics Data System (ADS)

Mogk, D. W.; Beane, R. J.; Whitney, D. L.; Nicolaysen, K. E.; Panero, W. R.; Peck, W. H.

2011-12-01

Mineralogy, petrology and geochemistry (MPG) are pillars of the geoscience curriculum because of their relevance in interpreting Earth history and processes, application to geo-hazards, resources, and environmental issues, and contributions to emerging fields such as geology and human health. To keep faculty current in scientific advances in these fields, and in modern instructional methods, the On the Cutting Edge program convened a workshop at the University of Minnesota in August, 2011. This workshop builds on the previous 15 year's work that has been focused on identifying, aggregating, and developing high-quality collections of teaching activities and related resources, and in building a community of scholars in support of excellence in instruction in MPG courses. The goals of the workshop were to: a) develop an integrated, comprehensive and reviewed curriculum for MPG courses, and to seek ways to make connections with the larger geoscience curriculum; b) to explore emerging topics in MPG such as geobiology and climate change; c) demonstrate effective methods in teaching MPG in the context of Earth system science; d) share effective teaching activities and strategies for the classroom, laboratory and field including advances in pedagogy, assessments and research on learning; e) keep faculty current on recent advances in mineralogy, petrology and geochemistry research and to apply these findings to our teaching; f) explore and utilize current societal and global issues that intersect mineralogy, petrology and geochemistry to heighten the relevancy of course content for students; and h) meet colleagues and foster future teaching and research collaborations. A significant outcome of this workshop is a peer reviewed of collection of 300+ existing teaching activities, and a gap analysis to identify teaching activities needed to make these collections comprehensive and coherent. In addition, a series of thematic collections were developed to assist high priority areas of teaching MPG (e.g. MPG in Introductory Geoscience Courses-Beyond "Rocks in a Box"; thermobarometry programs). All demonstrations and presentations made at the workshop are accessible from the workshop webpage, including a wide variety of active learning exercises and demonstrations of modern computer applications (e.g. SHAPE, ATOMS, CrystalMaker, MELTS, Theriak-Domino, Perplex, TWQ, Google Earth and Gigapans, and PHREEQC). A post-workshop field trip to the Precambrian rocks of northern Minnesota focused on effective teaching and learning in the field. We encourage the geoscience community to use these online resources, and please consider contributing additional teaching activities and resources to these collections.

Teaching Service Learning in the Geosciences: An On the Cutting Edge Workshop Report

NASA Astrophysics Data System (ADS)

Bruckner, M. Z.; Laine, E. P.; Mogk, D. W.; O'Connell, S.; Kirk, K. B.

2010-12-01

Service learning is an instructional method that combines community service and academic instruction within the context of an established academic course. It is a particularly effective approach that uses active and experiential learning to develop the academic skills required of a course of study and to simultaneously address authentic community needs. Service learning projects can energize and motivate students by engaging a sense of civic responsibility by working in concert with community partners. The geosciences provide abundant opportunities to develop service learning projects on topics related to natural hazards, resources, land use, water quality, community planning, public policy, and education (K-12 and public outreach). To explore the opportunities of teaching service learning in the geosciences, the On the Cutting Edge program convened an online workshop in February 2010. The goals of the workshop were to: 1) introduce the principles and practices of effective service learning instructional activities; 2) provide examples of successful service learning projects and practical advice about "what works;" 3) provide participants with the opportunity to design, develop, and refine their own service learning courses or projects; 4) develop collections of supporting resources related to the pedagogy of service learning; and 5) support a community of scholars interested in continued work on service learning in the geoscience curriculum. The workshop consisted of a series of web-based synchronous and asynchronous sessions, including presentations from experienced practitioners of service learning, panel discussions, threaded discussions, and editable web pages used to develop new material for the website. Time was also provided for small group and individual work and for participants to peer-review each others' service learning projects and to revise their own activities based on reviewer comments. Insights from the workshop were integrated into new web pages that can help others implement service learning projects in their own institutions and communities. Online resources developed by the workshop participants, conveners, and supporting staff include an assemblage of online and print resources, a searchable collection of peer-reviewed examples of service learning projects, a tutorial on using the "8-Block Model" to design and implement a service learning project, tips on finding service learning partners, advice on motivating students, departments and the community, and example assessment instruments. Faculty are encouraged to submit their own examples of additional service learning projects in the geosciences. The entire workshop program, resources and activities are available online at: http://serc.carleton.edu/NAGTWorkshops/servicelearning/index.html

US Geoscience Information Network, Web Services for Geoscience Information Discovery and Access

NASA Astrophysics Data System (ADS)

Richard, S.; Allison, L.; Clark, R.; Coleman, C.; Chen, G.

2012-04-01

The US Geoscience information network has developed metadata profiles for interoperable catalog services based on ISO19139 and the OGC CSW 2.0.2. Currently data services are being deployed for the US Dept. of Energy-funded National Geothermal Data System. These services utilize OGC Web Map Services, Web Feature Services, and THREDDS-served NetCDF for gridded datasets. Services and underlying datasets (along with a wide variety of other information and non information resources are registered in the catalog system. Metadata for registration is produced by various workflows, including harvest from OGC capabilities documents, Drupal-based web applications, transformation from tabular compilations. Catalog search is implemented using the ESRI Geoportal open-source server. We are pursuing various client applications to demonstrated discovery and utilization of the data services. Currently operational applications allow catalog search and data acquisition from map services in an ESRI ArcMap extension, a catalog browse and search application built on openlayers and Django. We are developing use cases and requirements for other applications to utilize geothermal data services for resource exploration and evaluation.

Preparing for a Professional Career in the Geosciences with AEG

NASA Astrophysics Data System (ADS)

Barry, T.; Troost, K. G.

2012-12-01

The Association of Environmental and Engineering Geologists offers multiple resources to students and faculty about careers in the geosciences, such as description of what employers are looking for, career options, mentoring, and building your professional network. Our website provides easy access to these and other resources. Most of AEG's 3000 members found their first job through association with another AEG member and more than 75% of our membership is working in applied geoscience jobs. We know that employers are looking for the following qualities: passion for your career and the geosciences, an enthusiastic personality, flexibility, responsibility, ability to communicate well in oral and written modes, and the ability to work well in teams or independently. Employers want candidates with a strong well-rounded geoscience education and the following skills/experience: attendance at field camp, working knowledge of field methodologies, strong oral and written communication skills, basic to advanced computer skills, and the ability to conduct research. In addition, skill with GIS applications, computer modeling, and 40-hour OSHA training are desired. The most successful technique for finding a job is to have and use a network. Students can start building their network by attending regular AEG or other professional society monthly meetings, volunteering with the society, attending annual meetings, going on fieldtrips and participating in other events. Students should research what kind of job they want and build a list of potential preferred employers, then market themselves to people within those companies using networking opportunities. Word-of-mouth sharing of job openings is the most powerful tool for getting hired, and if students have name recognition established within their group of preferred employers, job interviews will occur at a faster rate than otherwise.

Developing Short-Term Indicators of Recruitment and Retention in the Geosciences

NASA Astrophysics Data System (ADS)

Fuhrman, M.; Gonzalez, R.; Levine, R.

2004-12-01

The NSF Opportunities for Enhancing Diversity in the Geosciences (OEDG) program awards grants to projects that are intended to increase participation in geoscience careers by members of groups that have been traditionally underrepresented in the geosciences. OEDG grantee projects use a variety of strategies intended to influence the attitudes, beliefs, and behaviors of underrepresented students at levels from K-12 to graduate school. The ultimate criterion for assessing the success of a project is the number of underrepresented minority students who become geoscientists (and who would not have otherwise become geoscientists). For most projects this criterion can only be observed in the distant future. In order to develop shorter-term indicators of program success, researchers at AIR developed a conceptual framework based on a review of the literature and discussion with geoscientists. This model allowed us to identify an extensive, but not fully comprehensive, set of indicators. There are undoubtedly other potential indicators of recruitment and retention in the geosciences. The research literature reviewed was a general literature, dealing with science, technology, engineering, and/or mathematics (STEM) college major or career choice by individuals who are underrepresented group members, so the model is based on indicators of retention in a general STEM career path rather than a specific geoscience path. Nonetheless, it is our belief that retention in STEM is critical for retention in geoscience. In the past year, AIR staff have conducted a critical incident study to further refine this model. This study focused on factors unique to the geosciences. The goal was to learn about behaviors that encouraged or discouraged someone from becoming a geoscientist, where individual behaviors are termed as "incidents." The preliminary data, the impact of this pilot study on the model, and the revised model will be presented. Some examples of behaviors our study found that seem to affect an individual's decision on becoming a geoscientist include: parental support, exposure to geoscience classes, experience in the outdoors, experiencing extraordinary geosciences events, taking introductory geosciences course, accessibility of geoscience faculty, and participation in informal interactions and social activities in a geoscience department.

Weaving a knowledge network for Deep Carbon Science

NASA Astrophysics Data System (ADS)

Ma, Xiaogang; West, Patrick; Zednik, Stephan; Erickson, John; Eleish, Ahmed; Chen, Yu; Wang, Han; Zhong, Hao; Fox, Peter

2017-05-01

Geoscience researchers are increasingly dependent on informatics and the Web to conduct their research. Geoscience is one of the first domains that take lead in initiatives such as open data, open code, open access, and open collections, which comprise key topics of Open Science in academia. The meaning of being open can be understood at two levels. The lower level is to make data, code, sample collections and publications, etc. freely accessible online and allow reuse, modification and sharing. The higher level is the annotation and connection between those resources to establish a network for collaborative scientific research. In the data science component of the Deep Carbon Observatory (DCO), we have leveraged state-of-the-art information technologies and existing online resources to deploy a web portal for the over 1000 researchers in the DCO community. An initial aim of the portal is to keep track of all research and outputs related to the DCO community. Further, we intend for the portal to establish a knowledge network, which supports various stages of an open scientific process within and beyond the DCO community. Annotation and linking are the key characteristics of the knowledge network. Not only are key assets, including DCO data and methods, published in an open and inter-linked fashion, but the people, organizations, groups, grants, projects, samples, field sites, instruments, software programs, activities, meetings, etc. are recorded and connected to each other through relationships based on well-defined, formal conceptual models. The network promotes collaboration among DCO participants, improves the openness and reproducibility of carbon-related research, facilitates accreditation to resource contributors, and eventually stimulates new ideas and findings in deep carbon-related studies.

The Future of the Plate Boundary Observatory in the GAGE Facility and beyond 2018

NASA Astrophysics Data System (ADS)

Mattioli, G. S.; Bendick, R. O.; Foster, J. H.; Freymueller, J. T.; La Femina, P. C.; Miller, M. M.; Rowan, L.

2014-12-01

The Geodesy Advancing Geosciences and Earthscope (GAGE) Facility, which operates the Plate Boundary Observatory (PBO), builds on UNAVCO's strong record of facilitating research and education in the geosciences and geodesy-related engineering fields. Precise positions and velocities for the PBO's ~1100 continuous GPS stations and other PBO data products are used to address a wide range of scientific and technical issues across North America. A large US and international community of scientists, surveyors, and civil engineers access PBO data streams, software, and other on-line resources daily. In a global society that is increasingly technology-dependent, consistently risk-averse, and often natural resource-limited, communities require geodetic research, education, and infrastructure to make informed decisions about living on a dynamic planet. The western U.S. and Alaska, where over 95% of the PBO sensor assets are located, have recorded significant geophysical events like earthquakes, volcanic eruptions, and tsunami. UNAVCO community science provides first-order constraints on geophysical processes to support hazards mapping and zoning, and form the basis for earthquake and tsunami early warning applications currently under development. The future of PBO was discussed at a NSF-sponsored three-day workshop held in September 2014 in Breckenridge, CO. Over 40 invited participants and community members, including representatives from interested stakeholder groups, UNAVCO staff, and members of the PBO Working Group and Geodetic Infrastructure Advisory Committee participated in workshop, which included retrospective and prospective plenary presentations and breakout sessions focusing on specific scientific themes. We will present some of the findings of that workshop in order to continue a dialogue about policies and resources for long-term earth observing networks. How PBO fits into the recently released U.S. National Plan for Civil Earth Observations will also be discussed.

Geosciences Information Network (GIN): A modular, distributed, interoperable data network for the geosciences

NASA Astrophysics Data System (ADS)

Allison, M.; Gundersen, L. C.; Richard, S. M.; Dickinson, T. L.

2008-12-01

A coalition of the state geological surveys (AASG), the U.S. Geological Survey (USGS), and partners will receive NSF funding over 3 years under the INTEROP solicitation to start building the Geoscience Information Network (www.geoinformatics.info/gin) a distributed, interoperable data network. The GIN project will develop standardized services to link existing and in-progress components using a few standards and protocols, and work with data providers to implement these services. The key components of this network are 1) catalog system(s) for data discovery; 2) service definitions for interfaces for searching catalogs and accessing resources; 3) shared interchange formats to encode information for transmission (e.g. various XML markup languages); 4) data providers that publish information using standardized services defined by the network; and 5) client applications adapted to use information resources provided by the network. The GIN will integrate and use catalog resources that currently exist or are in development. We are working with the USGS National Geologic Map Database's existing map catalog, with the USGS National Geological and Geophysical Data Preservation Program, which is developing a metadata catalog (National Digital Catalog) for geoscience information resource discovery, and with the GEON catalog. Existing interchange formats will be used, such as GeoSciML, ChemML, and Open Geospatial Consortium sensor, observation and measurement MLs. Client application development will be fostered by collaboration with industry and academic partners. The GIN project will focus on the remaining aspects of the system -- service definitions and assistance to data providers to implement the services and bring content online - and on system integration of the modules. Initial formal collaborators include the OneGeology-Europe consortium of 27 nations that is building a comparable network under the EU INSPIRE initiative, GEON, Earthchem, and GIS software company ESRI. OneGeology-Europe and GIN have agreed to integrate their networks, effectively adopting global standards among geological surveys that are available across the entire field. ESRI is creating a Geology Data Model for ArcGIS software to be compatible with GIN, and other companies are expressing interest in adapting their services, applications, and clients to take advantage of the large data resources planned to become available through GIN.

The Geosciences Institute for Research and Education: Bringing awareness of the geosciences to minorities in Detroit MI

NASA Astrophysics Data System (ADS)

Nalepa, N. A.; Murray, K. S.; Napieralski, J. A.

2009-12-01

According to recent studies, more than 40% of students within the Detroit Public Schools (DPS) drop out and only 21% graduate within 4 years. In an attempt to improve these statistics, The Geosciences Institute for Research and Education was developed by the University of Michigan-Dearborn (UM-D) and funded by two grants from the National Science Foundation’s (NSF) OEDG Program. The Geosciences Institute, a collaboration between the UM-D, DPS, and local corporations, aims to generate awareness of the geosciences to middle school students, facilitate an enthusiastic learning environment, encourage underrepresented minorities to stay in school, and consider the geosciences as a viable career option. This is accomplished by involving their teachers, UM-D faculty and students, and local geoscience professionals in community-based research problems relevant to SE Michigan. Students use the geosciences as a tool in which they are actively participating in research that is in their backyards. Through a mixture of field trips, participation, and demonstrational activities the students become aware of local environmental and social problems and how a background in the geosciences can prepare them. As part of the Geosciences Institute, students participate in three ongoing research projects with UM-D faculty: (1) build, install, and monitor groundwater wells along the Lower Rouge River, (2) collect soil samples from and mapping brownfields in SW Detroit, and (3) learn basic GPS and GIS skills to map local natural resources. The students also work with faculty on creating video diaries that record ideas, experiences, and impressions throughout the Institute, including during fieldtrips, modules, research, and editing. Finally, small teams of students collaborate to design and print a poster that summarizes their experience in the Institute. The Geosciences Institute concludes with a ceremony that celebrates student efforts (posters and videos) and involves school administrators and teachers, faculty, and family. It is expected that this experience will generate enthusiasm for learning before entering high school and might lead some of these underrepresented students to pursue their education at UM-D, and possibly for a career in geology.

The Role of Geoscience Departments in Preparing Future Geoscience Professionals

NASA Astrophysics Data System (ADS)

Ormand, C. J.; MacDonald, H.; Manduca, C. A.

2010-12-01

The Building Strong Geoscience Departments program ran a workshop on the role of geoscience departments in preparing geoscience professionals. Workshop participants asserted that geoscience departments can help support the flow of geoscience graduates into the geoscience workforce by providing students with information about jobs and careers; providing experiences that develop career-oriented knowledge, attitudes and skills; encouraging exploration of options; and supporting students in their job searches. In conjunction with the workshop, we have developed a set of online resources designed to help geoscience departments support their students’ professional development in these ways. The first step toward sending geoscience graduates into related professions is making students aware of the wide variety of career options available in the geosciences and of geoscience employment trends. Successful means of achieving this include making presentations about careers (including job prospects and potential salaries) in geoscience classes, providing examples of practical applications of course content, talking to advisees about their career plans, inviting alumni to present at departmental seminars, participating in institutional career fairs, and publishing a departmental newsletter with information about alumni careers. Courses throughout the curriculum as well as co-curricular experiences can provide experiences that develop skills, knowledge, and attitudes that will be useful for a range of careers. Successful strategies include having an advisory board that offers suggestions about key knowledge and skills to incorporate into the curriculum, providing opportunities for students to do geoscience research, developing internship programs, incorporating professional skills training (such as HazMat training) into the curriculum, and teaching professionalism. Students may also benefit from involvement with the campus career center or from conducting informational interviews of geoscientists, and department faculty can support these activities simply by suggesting them to students and offering encouragement. Departments can also help students expand their career options by developing networks of alumni and potential employers. Alumni networks offer real-life examples of abstract career options, while networks of employers offer internship opportunities and a direct line to job openings. Finally, the power of simply talking to students directly should not be underestimated. Asking students about their career plans, offering them information on available options, encouraging them to apply for particular internships or jobs, or inviting them to meet with alumni who are visiting campus, can have a powerful impact. In all of this, we need to be supportive of student choices. Overall, faculty can help students make more informed career decisions and develop skills that will be of value in their career through a variety of strategies, working with students as an advisor or mentor to help them explore career options. Our website provides many examples of how geoscience departments across the country work toward these goals, as well as background information on topics such as geoscience employment trends.

Toward an automated parallel computing environment for geosciences

NASA Astrophysics Data System (ADS)

Zhang, Huai; Liu, Mian; Shi, Yaolin; Yuen, David A.; Yan, Zhenzhen; Liang, Guoping

2007-08-01

Software for geodynamic modeling has not kept up with the fast growing computing hardware and network resources. In the past decade supercomputing power has become available to most researchers in the form of affordable Beowulf clusters and other parallel computer platforms. However, to take full advantage of such computing power requires developing parallel algorithms and associated software, a task that is often too daunting for geoscience modelers whose main expertise is in geosciences. We introduce here an automated parallel computing environment built on open-source algorithms and libraries. Users interact with this computing environment by specifying the partial differential equations, solvers, and model-specific properties using an English-like modeling language in the input files. The system then automatically generates the finite element codes that can be run on distributed or shared memory parallel machines. This system is dynamic and flexible, allowing users to address different problems in geosciences. It is capable of providing web-based services, enabling users to generate source codes online. This unique feature will facilitate high-performance computing to be integrated with distributed data grids in the emerging cyber-infrastructures for geosciences. In this paper we discuss the principles of this automated modeling environment and provide examples to demonstrate its versatility.

What Next? Translating AGI's 2015 Guidelines for Ethical Professional Conduct into Practice

NASA Astrophysics Data System (ADS)

Boland, M. A.; Keane, C.

2016-12-01

In 2015, the American Geosciences Institute (AGI) published a revised version of the 1999 Guidelines for Ethical Professional Conduct, an aspirational document outlining ethical principles that should inform the professional behavior of all geoscientists. The revised Guidelines reflect a consensus of opinion among AGI's 51 member societies and show an evolution in thinking about geoscience ethics. The Guidelines also represent a foundational document to support the expansion of ethical guidelines by individual societies and organizations. Publishing the Guidelines was a significant milestone but aspirations need to be matched by action. We examine several developments that implement aspects of the Guidelines, including the development of a consensus statement regarding access and inclusion of individuals living with disabilities in the geosciences, a Joint AGI/Geological Society of America Societies meeting on professional conduct, geoethics training initiatives, and efforts to foster international cooperation in recognizing and implementing ethical practice in the geosciences. In addition, we examine the level of success in using these Guidelines as philosophical cornerstones for a number of international projects, such as Resourcing Future Generations and the International Raw Materials Observatory, that bring geoscience directly into contact with large societal issues.

Mars geoscience/climatology orbiter low cost mission operations

NASA Technical Reports Server (NTRS)

Erickson, K. D.

1984-01-01

It will not be possible to support the multiple planetary missions of the magnitude and order of previous missions on the basis of foreseeable NASA funding. It is, therefore, necessary to seek innovative means for accomplishing the goals of planetary exploration with modestly allocated resources. In this connection, a Core Program set of planetary exploration missions has been recommended. Attention is given to a Mission Operations design overview which is based on the Mars Geoscience/Climatology Orbiter Phase-A study performed during spring of 1983.

Systems, Society, Sustainability and the Geosciences: A Workshop to Create New Curricular Materials to Integrate Geosciences into the Teaching of Sustainability

NASA Astrophysics Data System (ADS)

Gosselin, D. C.; Manduca, C. A.; Oches, E. A.; MacGregor, J.; Kirk, K. B.

2012-12-01

Sustainability is emerging as a central theme for teaching about the environment, whether it be from the perspective of science, economics, or society. The Systems, Society, Sustainability and the Geosciences workshop provided 48 undergraduate faculty from 46 institutions a forum to discuss the challenges and possibilities for integrating geoscience concepts with a range of other disciplines to teach about the fundamentals of sustainability. Participants from community college to doctorate-granting universities had expertise that included geosciences, agriculture, biological sciences, business, chemistry, economics, ethnic studies, engineering, environmental studies, environmental education, geography, history, industrial technology, landscape design, philosophy, physics, and political science. The workshop modeled a range of teaching strategies that encouraged participants to network and collaborate, share successful strategies and materials for teaching sustainability, and identify opportunities for the development of new curricular materials that will have a major impact on the integration of geosciences into the teaching of sustainability. The workshop design provided participants an opportunity to reflect upon their teaching, learning, and curriculum. Throughout the workshop, participants recorded their individual and collective ideas in a common online workspace to which all had access. A preliminary synthesis of this information indicates that the concept of sustainability is a strong organizing principle for modern, liberal education requiring systems thinking, synthesis and contributions from all disciplines. Sustainability is inherently interdisciplinary and provides a framework for educational collaboration between and among geoscientists, natural/physical scientists, social scientists, humanists, engineers, etc.. This interdisciplinary framework is intellectually exciting and productive for educating students at all levels of higher education. Sustainability also provides a productive bridge from global to local issues, and vice versa. It has the potential to raise the value placed on faculty engagement with local resources and research questions, and to bring community-based stakeholders outside of academia into the classroom. There are many challenges that participants from geographically diverse parts of the country have in common, including the creation of new courses, and teaching interdisciplinary material beyond one's area of expertise. However, one of the greatest opportunities of using a sustainability theme is that it can be integrated into existing courses. It was also clear that incorporating one module on a sustainability topic can be stimulating and powerful mechanism for linking course content to real world issues. Two of the most important outcomes from the workshop were the creation of an online collection of activities and courses (http://serc.carleton.edu/integrate/workshops/sustainability2012/index.html) as well as the development of a community that can support integration of geoscience and issues of sustainability across the curriculum.

Recruitment Strategies for Geoscience Majors: Conceptual Framework and Practical Suggestions

NASA Astrophysics Data System (ADS)

Richardson, R. M.; Eyles, C.; Ormand, C. J.

2009-12-01

One characteristic of strong geoscience departments is that they recruit and retain quality students. In a survey to over 900 geoscience departments in the US and Canada several years ago nearly 90% of respondents indicated that recruiting and retaining students was important. Two years ago we offered a pre-GSA workshop on recruiting and retaining students that attracted over 30 participants from over 20 different institutions, from liberal arts colleges to state universities to research intensive universities. Since then we have sought additional feedback from a presentation to the AGU Heads & Chairs at a Fall AGU meeting, and most recently from a workshop on strengthening geoscience programs in June 2009. In all of these settings, a number of themes and concrete strategies have emerged. Key themes included strategies internal to the department/institution; strategies that reach beyond the department/institution; determining how scalable/transferable strategies that work in one setting are to your own setting; identifying measures of success; and developing or improving on an existing action plan specific to your departmental/institutional setting. The full results of all of these efforts to distill best practices in recruiting students will be shared at the Fall AGU meeting, but some of the best practices for strategies local to the department/institution include: 1) focusing on introductory classes (having the faculty who are most successful in that setting teach them, having one faculty member make a common presentation to all classes about what one can do with a geoscience major, offering topical seminars, etc.); 2) informing students of career opportunities (inviting alumni back to talk to students, using AGI resources, etc.,); 3) creating common space for students to work, study, and be a community; 4) inviting all students earning an ‘A’ (or ‘B’) in introductory classes to a departmental event just for them; and 5) creating a field trip for incoming freshmen, whether they are planning to major in geoscience or not. Some of the best practices for strategies reaching beyond the department include: 1) working with college/university academic advisors, admissions, career services, especially for undecided students; 2) working with local high schools and community colleges, especially for underrepresented students; and 3) advertising where students communicate (Facebook, Twitter, etc.). As important as recruitment strategies are, it is critical to have an assessment plan in place to measure the success of recruitment efforts. It takes effort and resources, often human capital, to recruit students. If enrollments increase, regardless of recruitment efforts, then scarce resources have been wasted. Some of the best assessment practices include: 1) surveying students, especially those who have recently declared a geoscience major; and 2) surveying students who have been recruited but who have not become majors.

Technical and Soft Skills Expectations During the Transition from Recent Graduate to New Hire

NASA Astrophysics Data System (ADS)

Keane, C. M.

2001-12-01

Employer-applicant skill compatibility represents a major component of the career development process, particularly for new entrants to the job market. Newly minted geoscientists largely bring a distinct set of skills learned during their formal education and training, which combined with a broader view of the person are evaluated for career potential in today's major employers. University departments possess a strong view of their role in educating future geoscientists, including the skill sets imparted, the basis of education provided, and the expectation for how their students will evolve into colleagues in the profession. Regretfully, based on numerous surveys by both the American Geological Institute's Human Resources program and other independent studies, the formally transferred skills and expectations do not necessarily match those of many geoscience employers. While academia has increased its focus on increasing technical skills and greater specialization, most geoscience employers have further increased the technology gap between themselves and academia, leading most employers to seek broadly trained and well-educated graduates. Additionally, soft skills represent an area of major disagreement between what is considered important and what is considered feasible in a formal education. While debate continues both within industry and academia over the ideal set of soft skills, the great variance in soft skill demands lead to better opportunities for matching of graduate to employer. This debate further enhances the ongoing discussion of the role of the university, the importance of employer needs, and the health of the geoscience discipline within society. Fundamentally, the hiring and career development process remains as sequence of compromises for both the employer and the recent graduate.

Geoscience Education Research, Development, and Practice at Arizona State University

NASA Astrophysics Data System (ADS)

Semken, S. C.; Reynolds, S. J.; Johnson, J.; Baker, D. R.; Luft, J.; Middleton, J.

2009-12-01

Geoscience education research and professional development thrive in an authentically trans-disciplinary environment at Arizona State University (ASU), benefiting from a long history of mutual professional respect and collaboration among STEM disciplinary researchers and STEM education researchers--many of whom hold national and international stature. Earth science education majors (pre-service teachers), geoscience-education graduate students, and practicing STEM teachers richly benefit from this interaction, which includes team teaching of methods and research courses, joint mentoring of graduate students, and collaboration on professional development projects and externally funded research. The geologically, culturally, and historically rich Southwest offers a superb setting for studies of formal and informal teaching and learning, and ASU graduates the most STEM teachers of any university in the region. Research on geoscience teaching and learning at ASU is primarily conducted by three geoscience faculty in the School of Earth and Space Exploration and three science-education faculty in the Mary Lou Fulton Institute and Graduate School of Education. Additional collaborators are based in the College of Teacher Education and Leadership, other STEM schools and departments, and the Center for Research on Education in Science, Mathematics, Engineering, and Technology (CRESMET). Funding sources include NSF, NASA, US Dept Ed, Arizona Board of Regents, and corporations such as Resolution Copper. Current areas of active research at ASU include: Visualization in geoscience learning; Place attachment and sense of place in geoscience learning; Affective domain in geoscience learning; Culturally based differences in geoscience concepts; Use of annotated concept sketches in learning, teaching, and assessment; Student interactions with textbooks in introductory courses; Strategic recruitment and retention of secondary-school Earth science teachers; Research-based professional development for STEM teachers; Design and evaluation of innovative transdisciplinary and online curricula; and Visitor cognition of geologic time and basic principles in Southwestern National Parks.

Teaching and Training in Geoinformatics: Experiences from the Cyberinfrastructure Summer Institute for Geoscientists (CSIG)

NASA Astrophysics Data System (ADS)

Smeekens, M.; Baru, C.; Keller, G. R.; Arrowsmith, R.; Crosby, C. J.

2009-12-01

The Cyberinfrastructure Summer Institute for Geoscientists (CSIG) has been conducted each year since 2004 under sponsorship of the GEON project that is funded by the NSF. The goal of the institute, which is broadly advertised to the Geoscience community, is to introduce geoscientists to Computer Science concepts and commonly-used as well as emergent information technology tools. The week-long program originally covered topics ranging from Data Modeling, Web Services, and Geographic Information Systems, to brief introductions to key concepts in Grid Computing, Parallel Programming, and Scientific Workflows. However, the program as well as the composition and expectations of the audience have evolved over time. Detailed course and instructor evaluations provide valuable feedback on course content and presentation approaches, and are used to plan future CSIG curriculum. From an initial emphasis on Geoscience graduate students and postdocs, the selection process has evolved to encourage participation by individuals with backgrounds in Geoscience as well as Computer Science from academia, government agencies, and industry. More recently, there has been an emphasis on selecting junior faculty and those interested in teaching Geoinformatics courses. While the initial objective of CSIG was to provide an overview of information technology topics via lectures and demonstrations, over time attendees have become more interested in specific instruction in how informatics and cyberinfrastructure (CI) capabilities could be utilized to address issues in Earth Science research and education. There have been requests over the years for more in-depth coverage on some topics and hands-on exercises. The program has now evolved to include a “Build Track”, focused on IT issues related to the development and implementation of Geoinformatics systems, and an “Education Track”, focused on use of Geoinformatics resources in education. With increasing awareness of CI projects, the audience is also becoming more interested in an introduction to the broader landscape of CI activities in the Geosciences and related areas. In the future, we plan a “demo” session to showcase various CI projects. Attendees will not only hear about such projects but will be able to use and experience the cyber-environments and tools in a hands-on session. The evolution of the CSIG program reflects major changes in the IT landscape since 2004. Where we once discussed Grid Computing, students are now learning about Cloud Computing and related concepts. An institute like CSIG play an important role in providing “cross-training” such that geoscientists gain insight into IT issues and solution approaches, while computer scientist gain a better appreciation of the needs and requirements of geoscience applications. In this presentation, we will summarize and analyze the trends over the years in program as well as audience composition; discuss lessons learnt over the years; and present our plan for future CSIG offerings.

Four Cornerstones for Ensuring a Sustainable Workforce and Opportunity for the Next Generation of Geoscientists

NASA Astrophysics Data System (ADS)

Keane, C. M.; Houlton, H. R.

2012-04-01

The great demographic shift underway in many developed nations is impacting the geosciences extraordinarily hard. We examine the situation in the United States as an example of how there are four clear overarching issues to establishing a sustainable geosciences workforce: Carrying Capacity of the Educational Sector, the fundamentals of meeting future demand, the issue of graduate quality, and the emerging challenge of sustaining the capacity building of future geoscientist generations. The United States currently hosts about half of all geoscientists globally and is facing the imminent, and in the case of the Federal geosciences workforce, attrition of the Baby Boom generation geoscientists. This demographic shift is impacting all parts of the geosciences and when coupled by internal shifts in the geosciences on subdisciplinary thrusts, the match between the skill portfolio of new graduates is not necessarily well-aligned with the exiting skills of retirees. In particular, the US geosciences face the challenge of, based on current demand, attrition, and graduation rates of being short nearly 150,000 geoscientists by 2021. At the same time, the educational community is seeing the retirement of faculty that are leading into constrained ability to educate students in a number of topics, especially those in the resource industries. Given current funding trends and priorities, this phenomenon is likely to be in a feedback loop and will complicate the broad skill portfolio of the future geosciences. We also examine the issues of global migration and how it does not appear to be nearly as important to addressing the challenges as assumed by many. In addition, the prospective future geosciences majors appear to be of lesser quality than even 5 years ago based on test score, yet we will also present several broad strategies and cautionary tales that can help the US, and likely the global, geosciences community to ensure a stable and effective future and how this is actually opening new opportunities for the next generation of geoscientists.

The IS-GEO RCN: Fostering Collaborations for Intelligent Systems Research to Support Geosciences

NASA Astrophysics Data System (ADS)

Gil, Y.; Pierce, S. A.

2016-12-01

Geoscience problems are complex and often involve data that changes across space and time. Frequently geoscience knowledge and understanding provides valuable information and insight for problems related to energy, water, climate, mineral resources, and our understanding of how the Earth evolves through time. Simultaneously, many grand challenges in the geosciences cannot be addressed without the aid of computational support and innovations. Intelligent and Information Systems (IS) research includes a broad range of computational methods and topics such as knowledge representation, information integration, machine learning, robotics, adaptive sensors, and intelligent interfaces. IS research has a very important role to play in accelerating the speed of scientific discovery in geosciences and thus in solving challenges in geosciences. Many aspects of geosciences (GEO) research pose novel open problems for intelligent systems researchers. To develop intelligent systems with sound knowledge of theory and practice, it is important that GEO and IS experts collaborate. The EarthCube Research Coordination Network for Intelligent Systems for Geosciences (IS-GEO RCN) represents an emerging community of interdisciplinary researchers producing fundamental new capabilities for understanding Earth systems. Furthermore, the educational component aims to identify new approaches to teaching students in this new interdisciplinary area, seeking to raise a new generation of scientists that are better able to apply IS methods and tools to geoscience challenges of the future. By providing avenues for IS and GEO researchers to work together, the IS-GEO RCN will serve as both a point of contact, as well as an avenue for educational outreach across the disciplines for the nascent community of research and practice. The initial efforts are focused on connecting the communities in ways that help researchers understand opportunities and challenges that can benefit from IS-GEO collaborations. The IS-GEO RCN will jumpstart interdisciplinary research collaborations in this emerging new area so that progress across both disciplines can be accelerated.

Evolving Frameworks for Different Communities of Scientists and End Users

NASA Astrophysics Data System (ADS)

Graves, S. J.; Keiser, K.

2016-12-01

Two evolving frameworks for interdisciplinary science will be described in the context of the Common Data Framework for Earth-Observation Data and the importance of standards and protocols. The Event Data Driven Delivery (ED3) Framework, funded by NASA Applied Sciences, provides the delivery of data based on predetermined subscriptions and associated workflows to various communities of end users. ED3's capabilities are used by scientists, as well as policy and resource managers, when event alerts are triggered to respond to their needs. The EarthCube Integration and Testing Environment (ECITE) Assessment Framework for Technology Interoperability and Integration is being developed to facilitate the EarthCube community's assessment of NSF funded technologies addressing Earth science problems. ECITE is addressing the translation of geoscience researchers' use cases into technology use case that apply EarthCube-funded building block technologies (and other existing technologies) for solving science problems. EarthCube criteria for technology assessment include the use of data, metadata and service standards to improve interoperability and integration across program components. The long-range benefit will be the growth of a cyberinfrastructure with technology components that have been shown to work together to solve known science objectives.

Energy Education Resources: Kindergarten through 12th Grade.

ERIC Educational Resources Information Center

Energy Information Administration (DOE), Washington, DC.

This resource guide provides students, educators, and other information users with a list of generally available free or low-cost energy-related educational materials. The 163 organizations listed are each related to the subject fields of coal, electricity, energy efficiency/energy conservation, the environment, geosciences/earth sciences, natural…

Expanding geothermal resource utilization through directed research, education, and public outreach: Final Technical Report

DOE Office of Scientific and Technical Information (OSTI.GOV)

Calvin, Wendy

The University of Nevada, Reno (UNR) conducts research and outreach activities that will lead to increased utilization of geothermal resources in the western US. The Great Basin Center for Geothermal Energy (GBCGE) is working in partnership with US industry to establish geothermal energy as a sustainable, environmentally sound, economically competitive contributor to energy supply in the western US. Task 1 involves conducting geoscience and engineering research and developing technology to improve the assessment, exploration, and stimulation of geothermal resources. Subtask projects were selected based on peer review of proposals submitted to the GBCGE from Nevada System of High Education (NSHE)more » institutions for short project development and seed awards intended to develop background and establish viability of approaches for future activities. Task 2 includes project management and organization of workshops periodically requested by DOE and others to satisfy other mission goals of the GBCGE and the DOE geothermal program. GBCGE supports interaction with national and international geothermal organizations, with brochures, presentations, and materials describing GBCGE accomplishments and current research. We continue to maintain and develop an internet-based information system that makes geothermal data and information available to industry, government, and academic stakeholders for exploration and development of geothermal resources. This award also partially supported post-doctoral scholar Drew Siler and research scientist Betsy Littlefield Pace whose effort is included under developing future research projects. Task 2 also focuses on education and outreach through a competitive graduate fellowship program. The budget is for two-year stipends for three graduate students to work collaboratively with GBCGE faculty on Master’s or PhD degrees in geoscience and engineering fields. This grant supported three MS students in full for two years toward the degree and contributed bridge money for four other students to finish their degrees. In total, eight graduate degrees were supported by this grant, either through the faculty seed grants or the fellowship program.« less

Retention of Women in Geoscience Undergraduate and Graduate Education at Caltech

NASA Astrophysics Data System (ADS)

Alexander, C. J.

2001-12-01

Institutional barriers encountered by women in undergraduate and graduate schools may take many forms, but can also be as simple as a lack of community support. In the 1990's the California Institute of Technology (Caltech) made a commitment to the retention of women in their graduate and undergraduate schools. Their program included mentoring, focussed tutoring, self-esteem support groups, and other retention efforts. Under this program, the attrition rate of women has dramatically slowed. In this paper, we will discuss recent data from the American Geological Institude chronicling the enrollment and successes of women in the geosciences, the program instituted by Caltech, possible causes of attrition among women in the geosciences, as well as potential programs to address these problems. We will also present, from the nationwide study, data on geoscience departments which have been relatively successful at retaining and graduating women in Earth and Space Sciences.

Undergraduate research projects help promote diversity in the geosciences

USGS Publications Warehouse

Young, De'Etra; Trimboli, Shannon; Toomey, Rick S.; Byl, Thomas D.

2016-01-01

A workforce that draws from all segments of society and mirrors the ethnic, racial, and gender diversity of the United States population is important. The geosciences (geology, hydrology, geospatial sciences, environmental sciences) continue to lag far behind other science, technology, engineering and mathematical (STEM) disciplines in recruiting and retaining minorities (Valsco and Valsco, 2010). A report published by the National Science Foundation in 2015, “Women, Minorities, and Persons with Disabilities in Science and Engineering” states that from 2002 to 2012, less than 2% of the geoscience degrees were awarded to African-American students. Data also show that as of 2012, approximately 30% of African-American Ph.D. graduates obtained a bachelor’s degree from a Historic Black College or University (HBCU), indicating that HBCUs are a great source of diverse students for the geosciences. This paper reviews how an informal partnership between Tennessee State University (a HBCU), the U.S. Geological Survey, and Mammoth Cave National Park engaged students in scientific research and increased the number of students pursuing employment or graduate degrees in the geosciences.

Oceanography and Geoscience Scholars at Texas A&M University Funded through the NSF S-STEM (Scholarships in Science, Technology, Engineering and Mathematics) Program

NASA Astrophysics Data System (ADS)

Richardson, M. J.; Gardner, W. D.

2016-02-01

Over the last seven years we have led the creation and implementation of the Oceanography and Geoscience Scholars programs at Texas A&M University. Through these programs we have been able to provide scholarship support for 92 undergraduates in Geosciences and 29 graduate students in Oceanography. Fifty-seven undergraduate scholars have graduated in Geosciences: 30 undergraduate students in Meteorology, 7 in Geology, and 20 in Environmental Geosciences. Two students have graduated in other STEM disciplines. Twenty-four students are in the process of completing their undergraduate degrees in STEM disciplines. Twenty-three students have graduated with MS or PhD degrees in Oceanography and five PhD students are completing their dissertations. As specified in the program solicitation all of the scholars are academically talented students with demonstrated financial need as defined by the FAFSA (Free Application for Federal Student Aid). We have endeavored to recruit students from underrepresented groups. One-third of the undergraduate scholars were from underrepresented groups; 28% of the graduate students. We will present the challenges and successes of these programs.

Opportunities at Geoscience in Veracruz

NASA Astrophysics Data System (ADS)

Welsh-Rodríguez, C.

2006-12-01

The State of Veracruz is located in the central part of the Gulf of Mexico. It has enormous natural, economic and cultural wealth, is the third most populous state in Mexico, with nearly 33 % of the nation's water resources. It has an enormous quantity of natural resources, including oil, and is strategically located in Mexico. On one hand, mountains to the east are a natural border on the other lies the Gulf of Mexico. Between these two barriers are located tropical forests, mountain forests, jungles, wetlands, reefs, etc., and the land is one of the richest in biodiversity within the Americas. Veracruz, because of its geographical characteristics, presents an opportunity for research and collaboration in the geosciences. The region has experienced frequent episodes of torrential rainfalls, which have caused floods resulting in large amounts of property damage to agriculture, housing, infrastructure and, in extreme situations, loss of human life. In 2004 Veracruz University initiated a bachelor degree in Geography, which will prepare professionals to use their knowledge of geosciences to understand and promote integrated assessment of the prevailing problems in the State. Along with the geography program, the Earth Science Center offers other research programs in seismology, vulcanology, climatology, sustainable development and global change. Because of these characteristics, Veracruz is an optimal environment for active research in the geosciences, as well as for sharing the results of this research with educators, students, and all learners. We look forward to facilitating these efforts in the coming years.

How Global Science has yet to Bridge Global Differences - A Status Report of the IUGS Taskforce on Global Geoscience Workforce

NASA Astrophysics Data System (ADS)

Keane, C. M.; Gonzales, L. M.

2010-12-01

The International Union of Geological Sciences, with endorsement by UNESCO, has established a taskforce on global geosciences workforce and has tasked the American Geological Institute to take a lead. Springing from a session on global geosciences at the IGC33 in Oslo, Norway, the taskforce is to address three issues on a global scale: define the geosciences, determine the producers and consumers of geoscientists, and frame the understandings to propose pathways towards improved global capacity building in the geosciences. With the combination of rapid retirements in the developed world, and rapid economic expansion and impact of resource and hazard issues in the developing world, the next 25 years will be a dynamic time for the geosciences. However, to date there has been little more than a cursory sense of who and what the geosciences are globally and whether we will be able to address the varied needs and issues in the developed and the developing worlds. Based on prior IUGS estimates, about 50% of all working geoscientists reside in the Unites States, and the US was also producing about 50% of all new geosciences graduate degrees globally. Work from the first year of the taskforce has elucidated the immense complexity of the issue of defining the geosciences, as it bring is enormous cultural and political frameworks, but also shed light on the status of the geosciences in each country. Likewise, this leads to issues of who is actually producing and consuming geoscience talent, and whether countries are meeting domestic demand, and if not, is external talent available to import. Many US-based assumptions about the role of various countries in the geosciences’ global community of people, namely China and India, appear to have been misplaced. In addition, the migration of geoscientists between countries raised enormous questions about what is nationality and if there is an ideal ‘global geoscientist.’ But more than anything, the taskforce is revealing clear global trends in geosciences education, both at the pre-college and university level and frame the state of health of geosciences education in the United States in a totally new light. But indicators are present that the developing world will likely overtake the developed world in the near future in the production of geoscientists, but a key question is will that fundamentally change the nature of the science given the social, cultural, and educational frameworks that the next global generation brings with them.

The Role of Introductory Geosciences in Students' Quantitative Literacy

NASA Astrophysics Data System (ADS)

Wenner, J. M.; Manduca, C.; Baer, E. M.

2006-12-01

Quantitative literacy is more than mathematics; it is about reasoning with data. Colleges and universities have begun to recognize the distinction between mathematics and quantitative literacy, modifying curricula to reflect the need for numerate citizens. Although students may view geology as 'rocks for jocks', the geosciences are truthfully rife with data, making introductory geoscience topics excellent context for developing the quantitative literacy of students with diverse backgrounds. In addition, many news items that deal with quantitative skills, such as the global warming phenomenon, have their basis in the Earth sciences and can serve as timely examples of the importance of quantitative literacy for all students in introductory geology classrooms. Participants at a workshop held in 2006, 'Infusing Quantitative Literacy into Introductory Geoscience Courses,' discussed and explored the challenges and opportunities associated with the inclusion of quantitative material and brainstormed about effective practices for imparting quantitative literacy to students with diverse backgrounds. The tangible results of this workshop add to the growing collection of quantitative materials available through the DLESE- and NSF-supported Teaching Quantitative Skills in the Geosciences website, housed at SERC. There, faculty can find a collection of pages devoted to the successful incorporation of quantitative literacy in introductory geoscience. The resources on the website are designed to help faculty to increase their comfort with presenting quantitative ideas to students with diverse mathematical abilities. A methods section on "Teaching Quantitative Literacy" (http://serc.carleton.edu/quantskills/methods/quantlit/index.html) focuses on connecting quantitative concepts with geoscience context and provides tips, trouble-shooting advice and examples of quantitative activities. The goal in this section is to provide faculty with material that can be readily incorporated into existing introductory geoscience courses. In addition, participants at the workshop (http://serc.carleton.edu/quantskills/workshop06/index.html) submitted and modified more than 20 activities and model courses (with syllabi) designed to use best practices for helping introductory geoscience students to become quantitatively literate. We present insights from the workshop and other sources for a framework that can aid in increasing quantitative literacy of students from a variety of backgrounds in the introductory geoscience classroom.

Recruiting a Diverse Set of Future Geoscientists through Outreach to Middle and High School Students and Teachers in Miami, Florida

NASA Astrophysics Data System (ADS)

Whitman, D.; Hickey-Vargas, R.; Draper, G.; Rego, R.; Gebelein, J.

2014-12-01

Florida International University (FIU), the State University of Florida in Miami is a large enrollment, federally recognized Minority Serving Institution with over 70% of the undergraduate population coming from groups underrepresented in the geoscience workforce. Recruiting local students into the geosciences is challenging because geology is not well integrated into the local school curriculum, the geology is poorly exposed in the low-relief south Florida region and many first generation college students are reluctant to enter unfamiliar fields. We describe and present preliminary findings from Growing Community Roots for the Geosciences in Miami, FL, a 2-year, NSF funded project run by the Department of Earth and Environment at FIU which aims to inform students enrolled in the local middle and high schools to educational and career opportunities in the geosciences. The project takes a multi-faceted approach which includes direct outreach through social media platforms and school visits, a 1-week workshop for middle school teachers and a 2-week summer camp aimed at high school students. An outreach team of undergraduate geoscience majors were recruited to build and maintain informational resources on Facebook, Instagram, Twitter and Google Plus and to accompany FIU faculty on visits to local middle schools and high schools. Both the teacher workshop and the summer camp included lectures on geoscience careers, fundamental concepts of solid earth and atmospheric science, hands on exercises with earth materials, fossils and microscopy, exercises with Google Earth imagery and GIS, and field trips to local geological sites and government facilities. Participants were surveyed at the beginning of the programs on their general educational background in math and science and their general attitudes of and interest in geoscience careers. Post program surveys showed significant increases in the comfort of teaching topics in geoscience among teachers and an increased interest in majoring in geoscience among students. On the final day of the programs, participants were queried on better ways of interesting high school to major in geoscience. Suggestions included visits by faculty and college students to high schools and using social media to promote events and activities.

Geoscience Academic Provenance: A Comparison of Undergraduate Students' Pathways to Faculty Pathways

NASA Astrophysics Data System (ADS)

Houlton, H. R.; Keane, C. M.; Wilson, C. E.

2012-12-01

Most Science, Technology, Engineering and Mathematics (STEM) disciplines have a direct recruiting method of high school science courses to supply their undergraduate majors. However, recruitment and retention of students into geoscience academic programs, who will be the future workforce, remains an important issue. The geoscience community is reaching a critical point in its ability to supply enough geoscientists to meet the current and near-future demand. Previous work done by Houlton (2010) determined that undergraduate geoscience majors follow distinct pathways when pursuing their degree and career. These pathways are comprised of students' interests, experiences, goals and career aspirations, which are depicted in six pathway steps. Three population groups were determined from the original 17 participants, which exhibited differences in pathway trajectories. Continued data collection efforts developed and refined the pathway framework. As part of an informal workshop activity, data were collected from 27 participants who are underrepresented minority early-career and future faculty in the geosciences. In addition, 20 geoscience departments' Heads and Chairs participated in an online survey about their pathway trajectories. Pathways were determined from each of these new sample populations and compared against the original geoscience undergraduate student participants. Several pathway components consistently spanned across sample populations. Identification of these themes have illuminated broad geoscience-related interests, experiences and aspirations that can be used to broadly impact recruitment and retention initiatives for our discipline. Furthermore, fundamental differences between participants' ages, stages in career and racial/ethnic backgrounds have exhibited subtle nuances in their geoscience pathway trajectories. In particular, those who've had research experiences, who think "creativity" is an important aspect of a geoscience career and those who want to share their knowledge with students may be more inclined to pursue academic positions. Indicators, like these, expand the pathway model and foster the development of a more robust framework for recruitment and retention in academia, as well as industry.

Retention and Mentorship of Minority Students via Undergraduate Internship Experiences

NASA Astrophysics Data System (ADS)

Cooper, P.

2004-12-01

The School of Ocean and Earth Science and Technology at the University of Hawaii is undertaking an Undergraduate Research Internship project to address the lack of full representation of women and underrepresented minorities in the geosciences. The overarching educational objective is to provide education and career development guidance and opportunities for students from underrepresented minorities. In collaboration with industry partners, we hope to prepare undergraduate students for life and careers in today's complex and dynamic technological world by encouraging them to attain high standards in the geosciences, thereby enabling them to compete successfully for positions in graduate programs. To achieve his goal, the project focuses on the following objectives: (1) Creating a high-quality integrated on-campus teaching and off-campus learning environment, and (2) providing an intensive introduction to geoscience careers through the guidance of experienced faculty and workplace mentors. The program will start small, collaborating with one or two companies over the next two years, offering paid summer internships. Opportunities for students include participation in geoscience-related research, obtaining experience in interpreting observations and providing information to end-users, working to improve technology and field methods, and developing the expertise to maintain, operate and deploy equipment. Program participants are assigned individual projects that relate to their academic majors, their career goals, and the ongoing research missions of our industry partners. In addition to their research activities, participants attend a series of seminars and tours dealing with current topics in geoscience to expose them to the wide variety of scientific and technical activities that occur in the workplace. The expected outcomes of this experience will be scientific growth and career development. Given that a very small percentage of all students go on to graduate school, strong mentoring relationships with a special advisor and/or professor who recognizes scientific potential will both aid in student retention in the field and encourage more applications to graduate school.

Launching an Academic Career: On the Cutting Edge Resources for Geoscience Graduate Students, Post-doctoral Fellows, and Early Career Faculty

NASA Astrophysics Data System (ADS)

Richardson, R. M.; Ormand, C. J.; MacDonald, H.; Dunbar, R. W.; Allen-King, R. M.; Manduca, C. A.

2010-12-01

Launching an academic career presents a number of challenges. A recent article in the Chronicle of Higher Education depicts academia as an “ivory sweatshop,” citing rising standards for tenure. Most graduate programs provide minimal training for life beyond graduate school. The professional development program “On the Cutting Edge” fills this gap by providing workshops and web resources on academic careers for graduate students, postdoctoral fellows, and early career faculty. These workshops and web resources address a wide range of topics related to teaching, research, and managing one’s career, tailored for each group. The Preparing for an Academic Career in the Geosciences workshop to help graduate students and postdoctoral fellows make the transition into an academic career has been offered annually since 2003. It provides a panel on academic careers in different institutional settings, sessions on research on learning, various teaching strategies, design of effective teaching activities, moving research forward to new settings, effective teaching and research statements, the job search process, negotiation, and presenting oneself to others. Complementary online resources (http://serc.carleton.edu/NAGTWorkshops/careerprep/index.html) focus on these topics. The workshops and web resources offer guidance for each step of the job search process, for developing and teaching one’s own courses, and for making the transition from being a research student to being in charge of a research program. Online resources also include case studies of successful dual career couples, documenting their job search strategies. A four-day workshop for Early Career Geoscience Faculty: Teaching, Research, and Managing Your Career, offered annually since 1999, provides sessions on teaching strategies, course design, developing a strategic plan for research, supervising student researchers, navigating departmental and institutional politics, preparing for tenure, time and task management, and more. Complementary online resources (http://serc.carleton.edu/NAGTWorkshops/earlycareer/index.html) also address these topics. The workshops and web resources offer guidance for becoming an efficient and effective teacher, for developing a thriving research program, for staying on track for tenure, and for managing a balance of one’s personal and professional lives. Online resources feature a collection of successful grant proposals, profiles of successful researchers and their collaborations with their students, and profiles of geoscience faculty from a variety of institutions describing how they achieve balance in their lives. Participants in both workshops overwhelmingly report that the workshop met or exceeded their expectations, that they feel much better prepared to move forward in their careers as a result of the workshops, and that they will use the website in the future. The two sets of web pages receive more than 7,000 visitors each month.

Live Interrogation and Visualization of Earth Systems (LIVES)

NASA Astrophysics Data System (ADS)

Nunn, J. A.; Anderson, L. C.

2007-12-01

Twenty tablet PCs and associated peripherals acquired through a HP Technology for Teaching grant are being used to redesign two freshman laboratory courses as well as a sophomore geobiology course in Geology and Geophysics at Louisiana State University. The two introductory laboratories serve approximately 750 students per academic year including both majors and non-majors; the geobiology course enrolls about 35 students/year and is required for majors in the department's geology concentration. Limited enrollments and 3 hour labs make it possible to incorporate hands-on visualization, animation, GIS, manipulation of data and images, and access to geological data available online. Goals of the course redesigns include: enhancing visualization of earth materials, physical/chemical/biological processes, and biosphere/geosphere history; strengthening student's ability to acquire, manage, and interpret multifaceted geological information; fostering critical thinking, the scientific method, and earth-system science/perspective in ancient and modern environments (such as coastal erosion and restoration in Louisiana or the Snowball Earth hypothesis); improving student communication skills; and increasing the quantity, quality, and diversity of students pursuing Earth Science careers. IT resources available in the laboratory provide students with sophisticated visualization tools, allowing them to switch between 2-D and 3-D reconstructions more seamlessly, and enabling them to manipulate larger integrated data- sets, thus permitting more time for critical thinking and hypothesis testing. IT resources also enable faculty and students to simultaneously work with simulation software to animate earth processes such as plate motions or groundwater flow and immediately test hypothesis formulated in the data analysis. Finally, tablet PCs make it possible for data gathering and analysis outside a formal classroom. As a result, students will achieve fluency in using visualization and technology for informal and formal scientific communication. The equipment and exercises developed also will be used in additional upper level undergraduate classes and two outreach programs: NSF funded Geoscience Alliance for Enhanced Minority Participation and Shell Foundation funded Shell Undergraduate Recruiting and Geoscience Education.

Ethical considerations in developing the next generation of geoscientists and defining a common cause for the geosciences

NASA Astrophysics Data System (ADS)

Keane, Christopher; Boland, Maeve

2017-04-01

Much of the discussion about ethics in geoscience centers around the ethical use of the science in a societal context or the social and professional conduct between individuals within the geoscience community. Little has been discussed about the challenges and ethical issues associated with the discipline's effort to build its future workforce in light of cyclical hiring, tightening research budgets, and rapidly evolving skill demands for professional geoscientists. Many geoscientists assume that the profession is underappreciated by society and insufficiently visible to students in higher education. Yet, at least in the United States, we are coming out of nearly a decade of record geoscience undergraduate enrollments and graduate programs that are operating at full capacity. During this time we have witnessed several fundamental shifts in the hiring demands for geoscientists, but in aggregate, have not seen any decrease in hiring of new graduates. The formal education system has not been able to respond to rapid changes in the skills required by employers and is producing a proportion of students unprepared to engage in a career as a geoscientist and, in some cases, unaware of the realities of business cycles and the need for professional and geographic mobility. Another problem for the future workforce is the lack of a fundamental rationale for the geosciences. Currently, the geosciences do not have a substantive vision for their role in society that can define the perception and destiny of the geosciences. During the Cold War and the Space Race, for example, advances in geoscience helped shape the next steps by society. Several initiatives, such as Resourcing Future Generations, are proposing research and social context frameworks for the geosciences that address critical global priorities, such as the Sustainable Development Goals. These projects may establish long-term trends and momentum that the discipline can build around. But what is the discipline's, and each of our individual, responsibility towards honest and nurtured development of the next generation, how we recruit future talent and disclose the opportunities and challenges of working in the geosciences, how we construct an educational system that meets the needs of students and society, and what constitutes a common cause for the geosciences?

How Do You Define an Internship?

NASA Astrophysics Data System (ADS)

Wilson, C. E.; Keane, C.

2017-12-01

According to the American Geosciences Institute's Geoscience Student Exit Survey, internship participation rates over the past four years have been low, particularly among bachelor's and doctoral graduates. In 2016, 65% of bachelor's graduates, 44% of master's graduates, and 57% of doctoral graduates did not participate in an internship while working on their degree. When asked if they submitted applications for internship opportunities, 42% of bachelor's graduates, 23% of master's graduates, and 46% of doctoral graduates claimed to not submit any applications. These statistics have raised concern at AGI because internships provide experiences that help develop critical professional skills and industry connections that can lead to jobs after graduation. However, when internships are discussed among various representatives in geoscience industries, there are disagreements in how an internship experience is defined. For example, opinions differ on whether REUs or other research experiences count as an internship. Clear definitions of internship opportunities may help academic faculty and advisors direct students towards these opportunities and help develop a collection of resources for finding future internships. This presentation will present some of the recent statistics on internship participation among geoscience graduates and present a series of questions to ascertain defining features of internships among AGU attendees and where help is needed to increase participation in internships among current geoscience students.

Volcanology curricula development aided by online educational resource

USGS Publications Warehouse

Poland, Michael P.; van der Hoeven Kraft, Katrien J.; Teasdale, Rachel

2011-01-01

Volcanic activity is an excellent hook for engaging college and university students in geoscience classes. An increasing number of Internet-accessible real-time and near–real time volcano monitoring data are now available and constitute an important resource for geoscience education; however, relatively few data sets are comprehensive, and many lack background information to aid in interpretation. In response to the need for organized, accessible, and well-documented volcano education resources, the U.S. Geological Survey's Hawaiian Volcano Observatory (HVO), in collaboration with NASA and the University of Hawai`i at Manoa, established the Volcanoes Exploration Project: Pu`u `Ō`ō (VEPP). The VEPP Web site (http://vepp.wr.usgs.gov) is an educational resource that provides access, in near real time, to geodetic, seismic, and geologic data from the active Pu`u `Ō`ō eruptive vent on Kilauea volcano, Hawaii, along with background and context information. A strength of the VEPP site is the common theme of the Pu`u `Ō`ō eruption, which allows the site to be revisited multiple times to demonstrate different principles and integrate many aspects of volcanology.

Brokering Capabilities for EarthCube - supporting Multi-disciplinary Earth Science Research

NASA Astrophysics Data System (ADS)

Jodha Khalsa, Siri; Pearlman, Jay; Nativi, Stefano; Browdy, Steve; Parsons, Mark; Duerr, Ruth; Pearlman, Francoise

2013-04-01

The goal of NSF's EarthCube is to create a sustainable infrastructure that enables the sharing of all geosciences data, information, and knowledge in an open, transparent and inclusive manner. Brokering of data and improvements in discovery and access are a key to data exchange and promotion of collaboration across the geosciences. In this presentation we describe an evolutionary process of infrastructure and interoperability development focused on participation of existing science research infrastructures and augmenting them for improved access. All geosciences communities already have, to a greater or lesser degree, elements of an information infrastructure in place. These elements include resources such as data archives, catalogs, and portals as well as vocabularies, data models, protocols, best practices and other community conventions. What is necessary now is a process for levering these diverse infrastructure elements into an overall infrastructure that provides easy discovery, access and utilization of resources across disciplinary boundaries. Brokers connect disparate systems with only minimal burdens upon those systems, and enable the infrastructure to adjust to new technical developments and scientific requirements as they emerge. Robust cyberinfrastructure will arise only when social, organizational, and cultural issues are resolved in tandem with the creation of technology-based services. This is a governance issue, but is facilitated by infrastructure capabilities that can impact the uptake of new interdisciplinary collaborations and exchange. Thus brokering must address both the cyberinfrastructure and computer technology requirements and also the social issues to allow improved cross-domain collaborations. This is best done through use-case-driven requirements and agile, iterative development methods. It is important to start by solving real (not hypothetical) information access and use problems via small pilot projects that develop capabilities targeted to specific communities. Brokering, as a critical capability for connecting systems, evolves over time through more connections and increased functionality. This adaptive process allows for continual evaluation as to how well science-driven use cases are being met. There is a near term, and possibly unique, opportunity through EarthCube and European e-Infrastructure projects to increase the impact and interconnectivity of projects. In the developments described in this presentation, brokering has been demonstrated to be an essential part of a robust, adaptive technical infrastructure and demonstration and user scenarios can address of both the governance and detailed implementation paths forward. The EarthCube Brokering roadmap proposes the expansion of brokering pilots into fully operational prototypes that work with the broader science and informatics communities to answer these questions, connect existing and emerging systems, and evolve the EarthCube infrastructure.

Diversity and Innovation for Geosciences (dig) Texas Earth and Space Science Instructional Blueprints

NASA Astrophysics Data System (ADS)

Ellins, K. K.; Bohls-Graham, E.; Riggs, E. M.; Serpa, L. F.; Jacobs, B. E.; Martinez, A. O.; Fox, S.; Kent, M.; Stocks, E.; Pennington, D. D.

2014-12-01

The NSF-sponsored DIG Texas Instructional Blueprint project supports the development of online instructional blueprints for a yearlong high school-level Earth science course. Each blueprint stitches together three-week units that contain curated educational resources aligned with the Texas state standards for Earth and Space Science and the Earth Science Literacy Principles. Units focus on specific geoscience content, place-based concerns, features or ideas, or other specific conceptual threads. Five regional teams composed of geoscientists, pedagogy specialists, and practicing science teachers chose unit themes and resources for twenty-two units during three workshops. In summer 2014 three Education Interns (Earth science teachers) spent six weeks refining the content of the units and aligning them with the Next Generation Science Standards. They also assembled units into example blueprints. The cross-disciplinary collaboration among blueprint team members allowed them to develop knowledge in new areas and to share their own discipline-based knowledge and perspectives. Team members and Education Interns learned where to find and how to evaluate high quality geoscience educational resources, using a web-based resource review tool developed by the Science Education Resource Center (SERC). SERC is the repository for the DIG Texas blueprint web pages. Work is underway to develop automated tools to allow educators to compile resources into customized instructional blueprints by reshuffling units within an existing blueprint, by mixing units from other blueprints, or creating new units and blueprints. These innovations will enhance the use of the units by secondary Earth science educators beyond Texas. This presentation provides an overview of the project, shows examples of blueprints and units, reports on the preliminary results of classroom implementation by Earth science teachers, and considers challenges encountered in developing and testing the blueprints. The project is a collaboration between The University of Texas at Austin, The University of Texas at El Paso, and Texas A&M University, all of which participate in the DIG Texas alliance. Website:serc.carleton.edu/dig_blueprints/index.html

Cloud Computing for Geosciences--GeoCloud for standardized geospatial service platforms (Invited)

NASA Astrophysics Data System (ADS)

Nebert, D. D.; Huang, Q.; Yang, C.

2013-12-01

The 21st century geoscience faces challenges of Big Data, spike computing requirements (e.g., when natural disaster happens), and sharing resources through cyberinfrastructure across different organizations (Yang et al., 2011). With flexibility and cost-efficiency of computing resources a primary concern, cloud computing emerges as a promising solution to provide core capabilities to address these challenges. Many governmental and federal agencies are adopting cloud technologies to cut costs and to make federal IT operations more efficient (Huang et al., 2010). However, it is still difficult for geoscientists to take advantage of the benefits of cloud computing to facilitate the scientific research and discoveries. This presentation reports using GeoCloud to illustrate the process and strategies used in building a common platform for geoscience communities to enable the sharing, integration of geospatial data, information and knowledge across different domains. GeoCloud is an annual incubator project coordinated by the Federal Geographic Data Committee (FGDC) in collaboration with the U.S. General Services Administration (GSA) and the Department of Health and Human Services. It is designed as a staging environment to test and document the deployment of a common GeoCloud community platform that can be implemented by multiple agencies. With these standardized virtual geospatial servers, a variety of government geospatial applications can be quickly migrated to the cloud. In order to achieve this objective, multiple projects are nominated each year by federal agencies as existing public-facing geospatial data services. From the initial candidate projects, a set of common operating system and software requirements was identified as the baseline for platform as a service (PaaS) packages. Based on these developed common platform packages, each project deploys and monitors its web application, develops best practices, and documents cost and performance information. This paper presents the background, architectural design, and activities of GeoCloud in support of the Geospatial Platform Initiative. System security strategies and approval processes for migrating federal geospatial data, information, and applications into cloud, and cost estimation for cloud operations are covered. Finally, some lessons learned from the GeoCloud project are discussed as reference for geoscientists to consider in the adoption of cloud computing.

Attracting Urban Minority Students to Geosciences through Exposure to Careers and Applied Aspects in Newark, NJ

NASA Astrophysics Data System (ADS)

Gates, A. E.; Kalczynski, M. J.

2014-12-01

A solid pipeline of URM students into the Geosciences has been established in Newark, NJ by introducing them to applied opportunities. Prior to an OEDG program designed to engage URM students, there were no students from or near Newark interested in pursuing geosciences at Rutgers-Newark or Essex Community College, the two local urban campuses. By infusing activities that showed the applied aspects of geoscience and opportunities for careers into regular high school lesson plans, a significant number of students became interested. These students were recruited into a 4-week modular summer institute that focused on energy, mining resources, environment and surface processes. About 90 students per year attended the institute which included 2 local field trips per week, presentations by industry professionals, activities that placed academic subjects into career perspective and a research project that directly affected the well-being of the students and their families. The most interested dozen of the 90 students were invited to participate in a high profile applied project that received significant media coverage, further enhancing their impression of the importance of geosciences. Previous graduates of the program were employed as assistants in subsequent programs to recycle the experience and enthusiasm. This had a positive effect on the persistence of the assistants who viewed themselves as role models to the younger students. The results are burgeoning numbers of URM geoscience majors at Rutgers, offering of geoscience for the first time in 30 years at Essex Community College as well as a new 2+2 geoscience track and several dual-credit courses at local high schools. An important aspect of this pathway or pipeline is that students must be able to clearly see the next step and their role in it. They are very tentative in this essentially pioneering pursuit. If they don't get a sense of a welcoming community and an ultimate career outcome, they quickly lose interest and retreat to a pursuit or major that is more traditional.

An Integrative and Collaborative Approach to Creating a Diverse and Computationally Competent Geoscience Workforce

NASA Astrophysics Data System (ADS)

Moore, S. L.; Kar, A.; Gomez, R.

2015-12-01

A partnership between Fort Valley State University (FVSU), the Jackson School of Geosciences at The University of Texas (UT) at Austin, and the Texas Advanced Computing Center (TACC) is engaging computational geoscience faculty and researchers with academically talented underrepresented minority (URM) students, training them to solve grand challenges . These next generation computational geoscientists are being trained to solve some of the world's most challenging geoscience grand challenges requiring data intensive large scale modeling and simulation on high performance computers . UT Austin's geoscience outreach program GeoFORCE, recently awarded the Presidential Award in Excellence in Science, Mathematics and Engineering Mentoring, contributes to the collaborative best practices in engaging researchers with URM students. Collaborative efforts over the past decade are providing data demonstrating that integrative pipeline programs with mentoring and paid internship opportunities, multi-year scholarships, computational training, and communication skills development are having an impact on URMs developing middle skills for geoscience careers. Since 1997, the Cooperative Developmental Energy Program at FVSU and its collaborating universities have graduated 87 engineers, 33 geoscientists, and eight health physicists. Recruited as early as high school, students enroll for three years at FVSU majoring in mathematics, chemistry or biology, and then transfer to UT Austin or other partner institutions to complete a second STEM degree, including geosciences. A partnership with the Integrative Computational Education and Research Traineeship (ICERT), a National Science Foundation (NSF) Research Experience for Undergraduates (REU) Site at TACC provides students with a 10-week summer research experience at UT Austin. Mentored by TACC researchers, students with no previous background in computational science learn to use some of the world's most powerful high performance computing resources to address a grand geosciences problem. Students increase their ability to understand and explain the societal impact of their research and communicate the research to multidisciplinary and lay audiences via near-peer mentoring, poster presentations, and publication opportunities.

Grid computing enhances standards-compatible geospatial catalogue service

NASA Astrophysics Data System (ADS)

Chen, Aijun; Di, Liping; Bai, Yuqi; Wei, Yaxing; Liu, Yang

2010-04-01

A catalogue service facilitates sharing, discovery, retrieval, management of, and access to large volumes of distributed geospatial resources, for example data, services, applications, and their replicas on the Internet. Grid computing provides an infrastructure for effective use of computing, storage, and other resources available online. The Open Geospatial Consortium has proposed a catalogue service specification and a series of profiles for promoting the interoperability of geospatial resources. By referring to the profile of the catalogue service for Web, an innovative information model of a catalogue service is proposed to offer Grid-enabled registry, management, retrieval of and access to geospatial resources and their replicas. This information model extends the e-business registry information model by adopting several geospatial data and service metadata standards—the International Organization for Standardization (ISO)'s 19115/19119 standards and the US Federal Geographic Data Committee (FGDC) and US National Aeronautics and Space Administration (NASA) metadata standards for describing and indexing geospatial resources. In order to select the optimal geospatial resources and their replicas managed by the Grid, the Grid data management service and information service from the Globus Toolkits are closely integrated with the extended catalogue information model. Based on this new model, a catalogue service is implemented first as a Web service. Then, the catalogue service is further developed as a Grid service conforming to Grid service specifications. The catalogue service can be deployed in both the Web and Grid environments and accessed by standard Web services or authorized Grid services, respectively. The catalogue service has been implemented at the George Mason University/Center for Spatial Information Science and Systems (GMU/CSISS), managing more than 17 TB of geospatial data and geospatial Grid services. This service makes it easy to share and interoperate geospatial resources by using Grid technology and extends Grid technology into the geoscience communities.

Advancing Earth System Science Literacy and Preparing the Future Geoscience Workforce Through Strategic Investments at the National Science Foundation (Invited)

NASA Astrophysics Data System (ADS)

Karsten, J. L.; Patino, L. C.; Rom, E. L.; Weiler, C. S.

2010-12-01

The National Science Foundation (NSF) is an independent federal agency created 60 years ago by the U.S. Congress "to promote the progress of science; to advance the national health, prosperity, and welfare; to secure the national defense…" NSF is the primary funding agency in the U.S. to support basic, frontier research across all fields in science, engineering, and education, except for medical sciences. With a FY 2011 budget request of more than $955 million, the NSF Directorate for Geosciences (GEO) is the principle source of federal funding for university-based fundamental research in the geosciences and preparation of the next generation of geoscientists. Since its inception, GEO has supported the education and training of a diverse and talented pool of future scientists, engineers, and technicians in the Earth, Ocean, Atmospheric and Geospatial Sciences sub-fields, through support of graduate research assistants, post-doctoral fellows, and undergraduate research experiences. In the late 1990’s and early 2000’s, GEO initiated several programs that expanded these investments to also support improvements in pre-college and undergraduate geoscience education through a variety of mechanisms (e.g., professional development support for K-12 teachers, development of innovative undergraduate curricula, and scientist-mentored research experiences for elementary and secondary students). In addition to GEO’s Geoscience Education (GeoEd), Opportunities for Enhancing Diversity in the Geosciences (OEDG), Global Learning and Observations to Benefit the Environment (GLOBE), and Geoscience Teacher Training (GEO-Teach) programs, GEO participates in a number of cross-Foundation programs, including the Research Experiences for Undergraduates (REU), Integrative Graduate Education and Research Traineeship (IGERT), Ethics Education in Science and Engineering (EESE), NSF Graduate STEM Fellows in K-12 Education (GK-12), and Partnerships for International Research and Education (PIRE) programs, and the new Climate Change Education Partnership (CCEP) program. Many broader impact activities associated with individual research grants supported by GEO contribute to the mix, through integration of research and education. Improving access to high quality geoscience education, developing educational resources and pedagogies that reflect current understandings based on cognitive research on how people learn science in formal and informal settings, cultivating a diverse talent pool for the future, and developing robust mechanisms to evaluate the quality of these various approaches and tools are challenges faced by the entire geosciences research and education community, not just NSF/GEO. In the past two years, GEO has worked collaboratively with the Education and Human Resources (EHR) Directorate, and sister agencies NOAA and NASA, to establish a new GEO Education and Diversity Strategic Framework, that will guide our investments in the future, and identify opportunities for a more cohesive, collaborative, and synergistic approach across NSF and the federal government. Details of this new strategic framework, results of recent program evaluations, and their implications for future NSF/GEO education program funding will be discussed.

Geoscience Education Research: The Role of Collaborations with Education Researchers and Cognitive Scientists

NASA Astrophysics Data System (ADS)

Manduca, C. A.; Mogk, D. W.; Kastens, K. A.; Tikoff, B.; Shipley, T. F.; Ormand, C. J.; Mcconnell, D. A.

2011-12-01

Geoscience Education Research aims to improve geoscience teaching and learning by understanding clearly the characteristics of geoscience expertise, the path from novice to expert, and the educational practices that can speed students along this path. In addition to expertise in geoscience and education, this research requires an understanding of learning -the domain of cognitive scientists. Beginning in 2002, a series of workshops and events focused on bringing together geoscientists, education researchers, and cognitive scientists to facilitate productive geoscience education research collaborations. These activities produced reports, papers, books, websites and a blog developing a research agenda for geoscience education research at a variety of scales: articulating the nature of geoscience expertise, and the overall importance of observation and a systems approach; focusing attention on geologic time, spatial skills, field work, and complex systems; and identifying key research questions in areas where new technology is changing methods in geoscience research and education. Cognitive scientists and education researchers played critical roles in developing this agenda. Where geoscientists ask questions that spring from their rich understanding of the discipline, cognitive scientists and education researchers ask questions from their experience with teaching and learning in a wide variety of disciplines and settings. These interactions tend to crystallize the questions of highest importance in addressing challenges of geoscience learning and to identify productive targets for collaborative research. Further, they serve as effective mechanisms for bringing research techniques and results from other fields into geoscience education. Working productively at the intersection of these fields requires teams of cognitive scientists, geoscientists, and education reserachers who share enough knowledge of all three domains to have a common articulation of the research problem, to make collaborative decisions, and to collectively problem solve. The development of this shared understanding is a primary result of the past decade of work. It has been developed through geoscience hosted events like the On the Cutting Edge emerging theme workshops and the Synthesis of Research on Thinking and Learning in the Geosciences project, complementary events in cognitive science and education that include geoscientists like the Gordon Conferences on Visualization in Science & Education or the Spatial Cognition conference series, and the interactions within and among geoscience education research projects like the Spatial Intelligence and Learning Center, the GARNET project, and many others. With this common ground in place, effective collaborations that bring together deep knowledge of psychology and brain function, of educational design and testing, and of time tested learning goals, teaching methods, and measures of success can flourish. A strong and accelerating research field has emerged that spans from work on basic cognitive skills important in geoscience, to studies of specific teaching strategies.

Information extraction and knowledge graph construction from geoscience literature

NASA Astrophysics Data System (ADS)

Wang, Chengbin; Ma, Xiaogang; Chen, Jianguo; Chen, Jingwen

2018-03-01

Geoscience literature published online is an important part of open data, and brings both challenges and opportunities for data analysis. Compared with studies of numerical geoscience data, there are limited works on information extraction and knowledge discovery from textual geoscience data. This paper presents a workflow and a few empirical case studies for that topic, with a focus on documents written in Chinese. First, we set up a hybrid corpus combining the generic and geology terms from geology dictionaries to train Chinese word segmentation rules of the Conditional Random Fields model. Second, we used the word segmentation rules to parse documents into individual words, and removed the stop-words from the segmentation results to get a corpus constituted of content-words. Third, we used a statistical method to analyze the semantic links between content-words, and we selected the chord and bigram graphs to visualize the content-words and their links as nodes and edges in a knowledge graph, respectively. The resulting graph presents a clear overview of key information in an unstructured document. This study proves the usefulness of the designed workflow, and shows the potential of leveraging natural language processing and knowledge graph technologies for geoscience.

A Survey of Geosensor Networks: Advances in Dynamic Environmental Monitoring

PubMed Central

Nittel, Silvia

2009-01-01

In the recent decade, several technology trends have influenced the field of geosciences in significant ways. The first trend is the more readily available technology of ubiquitous wireless communication networks and progress in the development of low-power, short-range radio-based communication networks, the miniaturization of computing and storage platforms as well as the development of novel microsensors and sensor materials. All three trends have changed the type of dynamic environmental phenomena that can be detected, monitored and reacted to. Another important aspect is the real-time data delivery of novel platforms today. In this paper, I will survey the field of geosensor networks, and mainly focus on the technology of small-scale geosensor networks, example applications and their feasibility and lessons learnt as well as the current research questions posed by using this technology today. Furthermore, my objective is to investigate how this technology can be embedded in the current landscape of intelligent sensor platforms in the geosciences and identify its place and purpose. PMID:22346721

Transforming Indigenous Geoscience Education and Research (TIGER)

NASA Astrophysics Data System (ADS)

Berthelote, A. R.

2014-12-01

American Indian tribes and tribal confed­erations exert sovereignty over about 20% of all the freshwater resources in the United States. Yet only about 30 Native American (NA) students receive bachelor's degrees in the geosci­ences each year, and few of those degrees are in the field of hydrology. To help increase the ranks of NA geoscientists,TIGER builds upon the momentum of Salish Kootenai College's newly accredited Hydrology Degree Program. It allows for the development and implementation of the first Bachelor's degree in geosciences (hydrology) at a Tribal College and University (TCU). TIGER integrates a solid educational research-based framework for retention and educational preparation of underrepresented minorities with culturally relevant curriculum and socio-cultural supports, offering a new model for STEM education of NA students. Innovative hydrology curriculum is both academically rigorous and culturally relevant with concurrent theoretical, conceptual, and applied coursework in chemical, biological, physical and managerial aspects of water resources. Educational outcomes for the program include a unique combination of competencies based on industry recognized standards (e.g., National Institute of Hydrologists), input from an experienced External Advisory Board (EAB), and competencies required for geoscientists working in critical NA watersheds, which include unique competencies, such as American Indian Water Law and sovereignty issues. TIGER represents a unique opportunity to capitalize on the investments the geoscience community has already made into broadening the participation of underrepresented minorities and developing a diverse workforce, by allowing SKC to develop a sustainable and exportable program capable of significantly increasing (by 25 to 75%) the National rate of Native American geoscience graduates.

Geoscience Through the Lens of Art: a collaborative course of science and art for undergraduates of various disciplines

NASA Astrophysics Data System (ADS)

Ellins, K. K.; Eriksson, S. C.; Samsel, F.; Lavier, L.

2017-12-01

A new undergraduate, upper level geoscience course was developed and taught by faculty and staff of the UT Austin Jackson School of Geosciences, the Center for Agile Technology, and the Texas Advanced Computational Center. The course examined the role of the visual arts in placing the scientific process and knowledge in a broader context and introduced students to innovations in the visual arts that promote scientific investigation through collaboration between geoscientists and artists. The course addressed (1) the role of the visual arts in teaching geoscience concepts and promoting geoscience learning; (2) the application of innovative visualization and artistic techniques to large volumes of geoscience data to enhance scientific understanding and to move scientific investigation forward; and (3) the illustrative power of art to communicate geoscience to the public. In-class activities and discussions, computer lab instruction on the application of Paraview software, reading assignments, lectures, and group projects with presentations comprised the two-credit, semester-long "special topics" course, which was taken by geoscience, computer science, and engineering students. Assessment of student learning was carried out by the instructors and course evaluation was done by an external evaluator using rubrics, likert-scale surveys and focus goups. The course achieved its goals of students' learning the concepts and techniques of the visual arts. The final projects demonstrated this, along with the communication of geologic concepts using what they had learned in the course. The basic skill of sketching for learning and using best practices in visual communication were used extensively and, in most cases, very effectively. The use of an advanced visualization tool, Paraview, was received with mixed reviews because of the lack of time to really learn the tool and the fact that it is not a tool used routinely in geoscience. Those senior students with advanced computer skills saw the importance of this tool. Students worked in teams, more or less effectively, and made suggestions for improving future offerings of the course.

Supporting REU Leaders and Effective Workforce Development in the Geosciences

NASA Astrophysics Data System (ADS)

Sloan, V.; Haacker, R.

2014-12-01

Research shows that research science experiences for undergraduates are key to the engagement of students in science, and teach critical thinking and communication, as well as the professional development skills. Nonetheless, undergraduate research programs are time and resource intensive, and program managers work in relative isolation from each other. The benefits of developing an REU community include sharing strategies and policies, developing collaborative efforts, and providing support to each other. This paper will provide an update on efforts to further develop the Geoscience REU network, including running a national workshop, an email listserv, workshops, and the creation of online resources for REU leaders. The goal is to strengthen the connections between REU community members, support the sharing of best practices in a changing REU landscape, and to make progress in formalizing tools for REU site managers.

Drawing on Experience: How Domain Knowledge Is Reflected in Sketches of Scientific Structures and Processes

NASA Astrophysics Data System (ADS)

Jee, Benjamin D.; Gentner, Dedre; Uttal, David H.; Sageman, Bradley; Forbus, Kenneth; Manduca, Cathryn A.; Ormand, Carol J.; Shipley, Thomas F.; Tikoff, Basil

2014-12-01

Capturing the nature of students' mental representations and how they change with learning is a primary goal in science education research. This can be challenging in spatially intense domains, such as geoscience, architecture, and engineering. In this research, we test whether sketching can be used to gauge level of expertise in geoscience, using new technology designed to facilitate this process. We asked participants with differing levels of geoscience experience to copy two kinds of geoscience images—photographs of rock formations and causal diagrams. To permit studying the process of sketching as well as the structure and content of the sketches, we used the CogSketch system (Forbus et al. 2011, Topics in Cognitive Science 3:648-666) to record the time course of sketching and analyze the sketches themselves. Relative to novices, geoscience students included more geological structures and relational symbols in their sketches of geoscience materials and were more likely to construct their sketches in a sequence consistent with the order of causal events. These differences appear to stem from differences in domain knowledge, because they did not show up in participants' sketches of materials from other fields. The findings and methods of this research suggest new ways to promote and assess science learning, which are well suited to the visual-spatial demands of many domains.

Unidata: A cyberinfrastrucuture for the geosciences

NASA Astrophysics Data System (ADS)

Ramamurthy, Mohan

2016-04-01

Data are the lifeblood of the geosciences. Rapid advances in computing, communications, and observational technologies - along with concomitant advances in high-resolution modeling, ensemble and coupled-systems predictions of the Earth system - are revolutionizing nearly every aspect of our field. The result is a dramatic proliferation of data from diverse sources; data that are consumed by an evolving and ever-broadening community of users and that are becoming the principal engine for driving scientific advances. Data-enabled research has emerged as a Fourth Paradigm of science, alongside experiments, theoretical studies, and computer simulations Unidata is a data facility, sponsored by the NSF, and our mission is to provide the data services, tools, and cyberinfrastructure leadership that advance Earth system science, enhance educational opportunities, and broaden participation in the geosciences. For more nearly thirty years, Unidata has worked in concert with the atmospheric science education and research community to develop and provide innovative data systems, tools, techniques, and resources to support data-enabled science to understand the Earth system. In doing so, Unidata has maintained a close, synergistic relationship with the universities, engaging them in collaborative efforts to exploit data and technologies, and removing roadblocks to data discovery, access, analysis, and effective use. As a community-governed program, Unidata depends on guidance and feedback from educators, researchers, and students in the atmospheric and related sciences. The Unidata Program helps researchers and educators acquire and use earth-related data. Most of the data are provided in "real time" or "near-real time" - that is, the data are sent to participants almost as soon as the observations are made. Unidata also develops, maintains, and supports a variety of software packages. Most of these packages are developed at the Unidata Program Center (UPC), while a few others originated externally, but are modified, maintained, and supported at the UPC. Software provided by Unidata is available at no charge. The overarching goal embodied in Unidata's strategic plan is the creation of a scientific ecosystem in which "data friction" is reduced and data transparency and ease-of-use are increased. In such an environment, scientists will expend less effort locating, acquiring, and processing data and more time interpreting their data and sharing knowledge. To accomplish the goals set forth in our strategic plan, Unidata has been working to build and provide cloud-based infrastructure that makes it easy to discover, access, integrate and use data from disparate geoscience disciplines, allowing investigators to perceive connections that today are obscured by incompatible data formats or the mistaken impression that the data they need for their investigations do not exist.

As Ethics is a Core Attribute of Science, So Geoethics Must Be at the Core of Geoscience

NASA Astrophysics Data System (ADS)

Cronin, V. S.; Bank, C.; Bobrowsky, P. T.; Geissman, J. W.; Kieffer, S. W.; Mogk, D. W.; Palinkas, C. M.; Pappas Maenz, C.; Peppoloni, S.; Ryan, A. M.

2015-12-01

The daily quest of a geoscientist is to seek reliable information about Earth: its history, nature, materials, processes, resources and hazards. In science, reliable information is based on reproducible observations (scientific facts), and includes an estimate of uncertainty. All geoscientists share that basic quest, regardless of whether they wear a lab coat, business suit or field boots at work. All geoscientists also share a responsibility to serve society - the same society that invested in science and education, and thereby enabled the development of geoscience as well as the commercial ventures that utilize geoscience. What does society expect in return for that investment? It just wants the truth, along with a clear indication of the uncertainty. Society needs reliable geoscience information and expertise so that it can make good, informed decisions about resources, risk and our shared environment. Unreliable geoscience information, if represented as valid, might do irreparable harm. The authors represent the International Association for Promoting Geoethics (IAPG, www.geoethics.org), which seeks to develop and advance geoethics worldwide. Geoethics is based on the moral imperative for geoscientists to use our knowledge and expertise about Earth for the benefit of humankind. Informed by the geologic record of the intertwined history of life and our planet, that moral imperative extends beyond our time, our culture, and even our species. Ultimately, Earth is a small lifeboat in space. Geoscientists form the essential interface between our human society and Earth, and we must act for the health and benefit of both. Einstein wrote, "Truth is what stands the test of experience." If geoscientists are unwilling to engage the public and to speak the truth about Earth, who else will assume that role? The challenges we face together - resources, energy, potable water, soil conservation, sea-level rise - are too serious for geoscientists to be mute. Voices motivated by narrow self-interest might fill the void left by our indifference. Our children's children's children will expect us to have done our job in our time: to be honest, to be good scientists, to provide reliable expertise about Earth, to help reorient society toward sustainability, and to pass on a healthy ecosystem to those who follow.

From The Horse's Mouth: Engaging With Geoscientists On Science

NASA Astrophysics Data System (ADS)

Katzenberger, J.; Morrow, C. A.; Arnott, J. C.

2011-12-01

"From the Horse's Mouth" is a project of the Aspen Global Change Institute (AGCI) that utilizes selected short video clips of scientists presenting and discussing their research in an interdisciplinary setting at AGCI as the core of an online interactive set of learning modules in the geosciences for grades 9-12 and 1st and 2nd year undergraduate students. The video archive and associated material as is has limited utility, but here we illustrate how it can be leveraged for educational purposes by a systematic mining of the resource integrated with a variety of supplemental user experiences. The project furthers several broad goals to: (a) improve the quality of formal and informal geoscience education with an emphasis on 9-12 and early undergraduate, (b) encourage and facilitate the engagement of geoscientists to strengthen STEM education by leveraging AGCI's interdisciplinary science program for educational purposes, (c) explore science as a human endeavor by providing a unique view of how scientists communicate in a research setting, potentially stimulating students to consider traditional and non-traditional geoscience careers, (d) promote student understanding of scientific methodology and inquiry, and (e) further student appreciation of the role of science in society, particularly related to understanding Earth system science and global change. The resource material at the core of this project is a videotape record of presentation and discussion among leading scientists from 35 countries participating in interdisciplinary workshops at AGCI on a broad array of geoscience topics over a period of 22 years. The unique archive represents approximately 1200 hours of video footage obtained over the course of 43 scientific workshops and 62 hours of public talks. The full spectrum of material represents scientists active on all continents with a diverse set of backgrounds and academic expertise in both natural and social sciences. We report on the video database resource, our data acquisition protocols, conceptual design for the learning modules, excerpts from the video archive illustrating both geoscience content utilized in educational module development and examples of video clips that explore the process of science and its nature as a human endeavor. A prototype of the user interface featuring a navigational strategy, a discussion of both content and process goals represented in the pilot material and its use in both formal and informal settings are presented.

Native Americans and the Geosciences: Problems With Societally Driven Research, Cultural and Racial Divisions

NASA Astrophysics Data System (ADS)

Redsteer, M. H.; James, K.

2004-12-01

Why are Native Americans absent from the geosciences? It doesn't seem to make sense when one view common to most traditional Native communities is earth and ecosystem stewardship, i.e. respect for Mother Earth. In addition, Native American communities could benefit from contributions made through earth science research. Land, and the natural resources that accompany it, are most tribes' greatest assets. Natural resource and land-use plans require information on geologic hazards, water quality and availability, soils, and environmentally sensitive areas: all data that are sorely lacking in Native communities. Native communities, with rapidly growing populations, desperately need geologic information for planning urban development. Even so, there are several reasons for a lack of interest in the geosciences: Mainstream science has historically served non-Native society to the detriment of Native communities, leaving few positive examples of earth science research for communities to draw from. Native North American communities have suffered greater harm from resource exploitation and have gained less from natural resource development than non-Native communities. Moreover, the earth scientist is usually the one who begins the assessing what is available for corporate exploitation, making the role of earth scientist adversarial. Racism, that begins at the elementary school level or earlier, leaves students feeling inadequate to pursue any degree, let alone those that are considered more challenging. Western science has a long history of denigrating indigenous knowledge and beliefs, producing a social stigma that Native American scientists must overcome. In addition, research tends to be narrowly focused, and based on the desire for individual academic achievement. This attitude counters cultural values of most Native groups, who seek to serve the collective group, rather than seeking self promotion.

EarthCube - A Community-led, Interdisciplinary Collaboration for Geoscience Cyberinfrastructure

NASA Astrophysics Data System (ADS)

Allison, M. L.; Keane, C. M.; Robinson, E.

2015-12-01

The EarthCube Test Enterprise Governance Project completed its initial two-year long process to engage the community and test a demonstration governing organization with the goal of facilitating a community-led process on designing and developing a geoscience cyberinfrastructure. Conclusions are that EarthCube is viable, has engaged a broad spectrum of end-users and contributors, and has begun to foster a sense of urgency around the importance of open and shared data. Levels of trust among participants are growing. At the same time, the active participants in EarthCube represent a very small sub-set of the larger population of geoscientists. Results from Stage I of this project have impacted NSF decisions on the direction of the EarthCube program. The overall tone of EarthCube events has had a constructive, problem-solving orientation. The technical and organizational elements of EarthCube are poised to support a functional infrastructure for the geosciences community. The process for establishing shared technological standards has notable progress but there is a continuing need to expand technological and cultural alignment. Increasing emphasis is being given to the interdependencies among EarthCube funded projects. The newly developed EarthCube Technology Plan highlights important progress in this area by five working groups focusing on: 1. Use cases; 2. Funded project gap analysis; 3. Testbed development; 4. Standards; and 5. Architecture. There is ample justification to continue running a community-led governance framework that facilitates agreement on a system architecture, guides EarthCube activities, and plays an increasing role in making the EarthCube vision of cyberinfrastructure for the geosciences operational. There is widespread community expectation for support of a multiyear EarthCube governing effort to put into practice the science, technical, and organizational plans that have and are continuing to emerge.

Communicating Geosciences with Policy-makers: a Grand Challenge for Academia

NASA Astrophysics Data System (ADS)

Harrison, W. J.; Walls, M. R.; Boland, M. A.

2015-12-01

Geoscientists interested in the broader societal impacts of their research can make a meaningful contribution to policy making in our changing world. Nevertheless, policy and public decision making are the least frequently cited Broader Impacts in proposals and funded projects within NSF's Geosciences Directorate. Academic institutions can play a lead role by introducing this societal dimension of our profession to beginning students, and by enabling interdisciplinary research and promoting communication pathways for experienced career geoscientists. Within the academic environment, the public interface of the geosciences can be presented through curriculum content and creative programs. These include undergraduate minors in economics or public policy designed for scientists and engineers, and internships with policy makers. Federal research institutions and other organizations provide valuable policy-relevant experiences for students. Academic institutions have the key freedom of mission to tackle interdisciplinary research challenges at the interface of geoscience and policy. They develop long-standing relationships with research partners, including national laboratories and state geological surveys, whose work may support policy development and analysis at local, state, regional, and national levels. CSM's Payne Institute for Earth Resources awards mini-grants for teams of researchers to develop collaborative research efforts between engineering/science and policy researchers. Current work in the areas of nuclear generation and the costs of climate policy and on policy alternatives for capturing fugitive methane emissions are examples of work at the interface between the geosciences and public policy. With academic engagement, geoscientists can steward their intellectual output when non-scientists translate geoscience information and concepts into action through public policies.

Inter-agency Working Group for Airborne Data and Telemetry Systems (IWGADTS)

NASA Technical Reports Server (NTRS)

Webster, Chris; Freudinger, Lawrence; Sorenson, Carl; Myers, Jeff; Sullivan, Don; Oolman, Larry

2009-01-01

The Interagency Coordinating Committee for Airborne Geosciences Research and Applications (ICCAGRA) was established to improve cooperation and communication among agencies sponsoring airborne platforms and instruments for research and applications, and to serve as a resource for senior level management on airborne geosciences issues. The Interagency Working Group for Airborne Data and Telecommunications Systems (IWGADTS) is a subgroup to ICCAGRA for the purpose of developing recommendations leading to increased interoperability among airborne platforms and instrument payloads, producing increased synergy among research programs with similar goals, and enabling the suborbital layer of the Global Earth Observing System of Systems.

GeoX: A New Pre-college Program to Attract Underrepresented Minorities and First Generation Students to the Geosciences

NASA Astrophysics Data System (ADS)

Miller, K. C.; Garcia, S. J.; Houser, C.; GeoX Team

2011-12-01

An emerging challenge in science, technology, engineering and math (STEM) education is the recruitment of underrepresented groups in those areas of the workforce. This paper describes the structure and first-year results of the Geosciences Exploration Summer Program (GeoX) at Texas A&M University. Recent evidence suggest that pipeline programs should target junior and senior high school students who are beginning to seriously consider future career choices and appropriate college programs. GeoX is an overnight program that takes place during the summer at Texas A&M University. Over the course of a week, GeoX participants interact with faculty from the College of Geosciences, administrators, current students, and community leaders through participation in inquiry-based learning activities, field trips, and evening social events. The aim of this project is to foster a further interest in pursuing geosciences as an undergraduate major in college and thereby increase participation in the geosciences by underrepresented ethnic minority students. With funding from industry and private donors, high achieving rising junior and rising senior students, with strong interest in science and math, were invited to participate in the program. Students and their parents were interviewed before and after the program to determine if it was successful in introducing and enhancing awareness of the: 1) various sub-disciplines in the geosciences, 2) benefits of academia and research, 3) career opportunities in each of those fields and 4) college admission process including financial aid and scholarship opportunities. Results of the survey suggest that the students had a very narrow and stereotypical view of the geosciences that was almost identical to the views of their parents. Following the program, the students had a more expanded and positive view of the geosciences compared to the pre-program survey and compared to their parents. While it remains to be seen how many of those students will apply to a geosciences program, the level of interest and the number of students identifying the geosciences as a likely college and career choice greatly increased. Students identified the wide range of field and laboratory activities (including atmospheric soundings, GPR, coring, etc.) and the excitement of the faculty involved as key aspects of the program and for introducing and enhancing their view of the geosciences.

DIG Texas Blueprints - Pathways for Teaching a Rigorous Earth Science Course

NASA Astrophysics Data System (ADS)

Ellins, K. K.; Riggs, E. M.; Serpa, L. F.; Pennington, D. D.; Fox, S.; Larsen, K.; Ledley, T. S.; Stocks, E.; Mosher, S.; Miller, K. C.

2013-12-01

The DIG (Diversity and Innovation for Geosciences) Texas Instructional Blueprint project supports the development of five online instructional blueprints that document what to teach in a yearlong high school-level Earth science course. Each blueprint stitches together units that contain approximately 10 well-vetted, curated educational resources and learning activities. Units may focus on specific geoscience content, place-based concerns, features or ideas, or other specific conceptual threads. Five regional teams composed of Earth scientists, pedagogy specialists, and practicing science teachers are creating the blueprints. The cross-disciplinary collaboration among blueprint team members provides opportunities for them to develop knowledge in new areas and to share their own discipline-based knowledge and perspectives. Team members also learn where to find and how to evaluate high quality geoscience educational resources, using a web-based resource review tool. Blueprint development is guided by the Next Generation Science Standards and selected educational resources are aligned with the Texas state standards (Texas Essential Knowledge and Skills) for Earth and Space Science and the Earth Science Literacy Principles. The Science Education Resource Center (SERC) serves as the repository for the DIG Texas blueprint web pages. The Cyber-ShARE Center of Excellence at UTEP and SERC are engaged in the development of automated tools to allow educators to compile resources into customized instructional blueprints by reshuffling units within an existing blueprint, by mixing and matching units from other blueprints, or creating new units and blueprints. These innovations are intended to provide access to the blueprints in such a way that enhances their use by secondary Earth science educators. In this presentation, we provide an overview of the project, showcase examples of the blueprints, report on the preliminary results of classroom implementation, and consider challenges encountered in developing and testing the blueprints. Sponsored by NSF, the DIG Texas Instructional Blueprint project is a collaborative effort that draws on the resources of three major research universities, The University of Texas at Austin, The University of Texas at El Paso, and Texas A&M University, all of which are members of the DIG Texas alliance.

GET21: Geoinformatics Training and Education for the 21st Century Geoscience Workforce

NASA Astrophysics Data System (ADS)

Baru, C.; Allison, L.; Fox, P.; Keane, C.; Keller, R.; Richard, S.

2012-04-01

The integration of advanced information technologies (referred to as cyberinfrastructure) into scientific research and education creates a synergistic situation. On the one hand, science begins to move at the speed of information technology, with science applications having to move rapidly to keep apace with the latest innovations in hardware and software. On the other hand, information technology moves at the pace of science, requiring rapid prototyping and rapid development of software and systems to serve the immediate needs of the application. The 21st century geoscience workforce must be adept at both sides of this equation to be able to make the best use of the available cyber-tools for their science and education endeavors. To reach different segments of the broad geosciences community, an education program in geoinformatics must be multi-faceted, ranging from areas dealing with modeling, computational science, and high performance computing, to those dealing with data collection, data science, and data-intensive computing. Based on our experience in geoinformatics and data science education, we propose a multi-pronged approach with a number of different components, including summer institutes typically aimed at graduate students, postdocs and researchers; graduate and undergraduate curriculum development in geoinformatics; development of online course materials to facilitate asynchronous learning, especially for geoscience professionals in the field; provision of internship at geoinformatics-related facilities for graduate students, so that they can observe and participate in geoinformatics "in action"; creation of online communities and networks to facilitate planned as well as serendipitous collaborations and for linking users with experts in the different areas of geoscience and geoinformatics. We will describe some of our experiences and the lessons learned over the years from the Cyberinfrastructure Summer Institute for Geoscientists (CSIG), which is a 1-week institute that has been held each summer (August) at the San Diego Supercomputer Center, University of California, San Diego, since 2005. We will also discuss these opportunities for GET21 and geoinformatics education in the context of the newly launched EarthCube initiative at the US National Science Foundation.

Selected worldwide coal activities of the U.S. Geological Survey, with emphasis on their environmental applications

DOE Office of Scientific and Technical Information (OSTI.GOV)

SanFilipo, J.R.; Warwick, P.D.

1995-12-31

Many of the underdeveloped and developing nations of the world face severe shortages of energy fuels, and many of the industrialized nations that are abandoning centrally-planned economies face collapsing energy distribution networks. These energy-poor nations are typically among the most environmentally stressed. This results in part from the direct effects of outmoded energy technologies and the low quality of available fuel, but it is also a result of the poverty and lack of social and technological infrastructure that invariably attends energy deficits. For such nations, the orderly development of underutilized indigenous coal resources and the upgrading of existing coal technologiesmore » can lead to economically viable sources of energy that are relatively benign from an environmental standpoint, and can contribute to long-term political stability as well. The US Geological Survey has participated in coal studies in a variety of such international settings in recent years. Most of these studies have been commodity related, focusing on coal resource assessments in nations with acute energy shortages and coal quality studies in areas where development has had recognizable environmental impacts. Training of counterparts from the host countries and the transfer of technology are an integral part of the international programs, with the primary goal of developing the ability of the host country to integrate geosciences into energy-policy decision-making.« less

Assessment of undiscovered conventional oil and gas resources of the Western Canada Sedimentary Basin, Canada, 2012

USGS Publications Warehouse

Higley, Debra K.

2013-01-01

The U.S. Geological Survey recently completed a geoscience-based assessment of undiscovered oil and gas resources of provinces within the Western Canada Sedimentary Basin. The Western Canada Sedimentary Basin primarily comprises the (1) Alberta Basin Province of Alberta, eastern British Columbia, and the southwestern Northwest Territories; (2) the Williston Basin Province of Saskatchewan, southeastern Alberta, and southern Manitoba; and (3) the Rocky Mountain Deformed Belt Province of western Alberta and eastern British Columbia. This report is part of the U.S. Geological Survey World Petroleum Resources Project assessment of priority geologic provinces of the world. The assessment was based on geoscience elements that define a total petroleum system (TPS) and associated assessment unit(s). These elements include petroleum source rocks (geochemical properties and petroleum generation, migration, and accumulation), reservoir description (reservoir presence, type, and quality), and petroleum traps (trap and seal types, and timing of trap and seal formation relative to petroleum migration). Using this framework, the Elk Point-Woodbend Composite TPS, Exshaw-Fernie-Mannville Composite TPS, and Middle through Upper Cretaceous Composite TPS were defined, and four conventional assessment units within the total petroleum systems were quantitatively assessed for undiscovered resources in the Western Canada Sedimentary Basin.

AMS Professional Development Courses: Arming K-12 Teachers with the Tools Needed to Increase Students' Scientific Literacy

NASA Astrophysics Data System (ADS)

Brey, J. A.; Geer, I. W.; Weinbeck, R. S.; Moran, J. M.; Nugnes, K. A.

2012-12-01

To better prepare tomorrow's leaders, it is of utmost importance that today's teachers are science literate. To meet that need, the American Meteorological Society (AMS) Education Program offers content-rich, professional development courses and training workshops for precollege teachers in the geosciences. During the fall and spring semesters, the AMS in partnership with NOAA, NASA, and SUNY Brockport, offers a suite of pre-college teacher development courses, DataStreme Atmosphere, DataStreme Ocean and DataStreme Earth's Climate System (ECS). These courses are delivered to small groups of K-12 teachers through Local Implementation Teams (LITs) positioned throughout the U.S. The courses use current, real-world environmental data to investigate the atmosphere, ocean, and climate system and consist of weekly online study materials, weekly mentoring, and several face-to-face meetings, all supplemented by a provided textbook and investigations manual. DataStreme ECS takes an innovative approach to studying climate science, by exploring the fundamental science of Earth's climate system and addressing the societal impacts relevant to today's students and teachers. The course investigates natural and human forcings and feedbacks to examine mitigation and adaptation strategies for the future. Information and data from respected organizations, such as the IPCC, the US Global Change Research Program, NASA, and NOAA are used throughout the course, including in the online and printed investigations. In addition, participants differentiate between climate, climate variability, and climate change through the AMS Conceptual Energy Model, a basic climate model that follows the flow of energy from space to Earth and back. Participants also have access to NASA's EdGCM, a research-grade Global Climate Model where they can explore various future climate scenarios in the same way that actual research scientists do. Throughout all of the courses, teachers have the opportunity to expand their knowledge in the geosciences and incorporate technology into their classrooms by utilizing state-of-the-art resources from NOAA, NASA, and other lead scientific organizations. Upon completion of each course, teachers receive three free graduate credits from SUNY Brockport. The DataStreme courses have directly trained almost 17,000 teachers, impacting over one million students. The DataStreme courses have increased teachers' geoscience knowledge, pointing them to the resources available online, and building their confidence in understanding dynamic Earth systems. Through courses modeled on scientific inquiry and fashioned to develop critical thinking skills, these teachers become a resource for their classrooms and colleagues.

Building a Semantic Framework for eScience

NASA Astrophysics Data System (ADS)

Movva, S.; Ramachandran, R.; Maskey, M.; Li, X.

2009-12-01

The e-Science vision focuses on the use of advanced computing technologies to support scientists. Recent research efforts in this area have focused primarily on “enabling” use of infrastructure resources for both data and computational access especially in Geosciences. One of the existing gaps in the existing e-Science efforts has been the failure to incorporate stable semantic technologies within the design process itself. In this presentation, we describe our effort in designing a framework for e-Science built using Service Oriented Architecture. Our framework provides users capabilities to create science workflows and mine distributed data. Our e-Science framework is being designed around a mass market tool to promote reusability across many projects. Semantics is an integral part of this framework and our design goal is to leverage the latest stable semantic technologies. The use of these stable semantic technologies will provide the users of our framework the useful features such as: allow search engines to find their content with RDFa tags; create RDF triple data store for their content; create RDF end points to share with others; and semantically mash their content with other online content available as RDF end point.

Modeling the Impact of Deformation on Unstable Miscible Displacements in Porous Media

NASA Astrophysics Data System (ADS)

Santillán, D.; Cueto-Felgueroso, L.

2014-12-01

Coupled flow and geomechanics is a critical research challenge in engineering and the geosciences. The simultaneous flow of two or more fluids with different densities or viscosities through deformable media is ubiquitous in environmental, industrial, and biological processes, including the removal of non-aqueous phase liquids from underground water bodies, the geological storage of CO2, and current challenges in energy technologies, such as enhanced geothermal systems, unconventional hydrocarbon resources or enhanced oil recovery techniques. Using numerical simulation, we study the interplay between viscous-driven flow instabilities (viscous fingering) and rock mechanics, and elucidate the structure of the displacement patterns as a function of viscosity contrast, injection rate and rock mechanical properties. Finally, we discuss the role of medium deformation on transport and mixing processes in porous media.

Geoscience Diversity Experiential Simulations (GeoDES) Workshop Report

NASA Astrophysics Data System (ADS)

Houlton, H. R.; Chen, J.; Brown, B.; Samuels, D.; Brinkworth, C.

2017-12-01

The geosciences have to solve increasingly complex problems relating to earth and society, as resources become limited, natural hazards and changes in climate impact larger communities, and as people interacting with Earth become more interconnected. However, the profession has dismally low representation from geoscientists who are from diverse racial, ethnic, or socioeconomic backgrounds, as well as women in leadership roles. This underrepresentation also includes individuals whose gender identity/expression is non-binary or gender-conforming, or those who have physical, cognitive, or emotional disabilities. This lack of diversity ultimately impacts our profession's ability to produce our best science and work with the communities that we strive to protect and serve as stewards of the earth. As part of the NSF GOLD solicitation, we developed a project (Geoscience Diversity Experiential Simulations) to train 30 faculty and administrators to be "champions for diversity" and combat the hostile climates in geoscience departments. We hosted a 3-day workshop in November that used virtual simulations to give participants experience in building the skills to react to situations regarding bias, discrimination, microaggressions, or bullying often cited in geoscience culture. Participants interacted with avatars on screen, who responded to participants' actions and choices, given certain scenarios. The scenarios are framed within a geoscience perspective; we integrated qualitative interview data from informants who experienced inequitable judgement, bias, discrimination, or harassment during their geoscience careers. The simulations gave learners a safe environment to practice and build self-efficacy in how to professionally and productively engage peers in difficult conversations. In addition, we obtained pre-workshop survey data about participants' understanding regarding Diversity, Equity, and Inclusion practices, as well as observation data of participants' responses during the simulations. Follow-up activities include monthly online meetings to engage problem solving and strategy-building skills for catalyzing institutional culture change within departments. This talk will specifically focus on workshop observations and preliminary reactions to the training.

PROGRESS (PROmoting Geoscience Research Education and SuccesS): a novel mentoring program for retaining undergraduate women in the geosciences

NASA Astrophysics Data System (ADS)

Clinton, Sandra; Adams, Amanda; Barnes, Rebecca; Bloodhart, Brittany; Bowker, Cheryl; Burt, Melissa; Godfrey, Elaine; Henderson, Heather; Hernandez, Paul; Pollack, Ilana; Sample McMeeking, Laura Beth; Sayers, Jennifer; Fischer, Emily

2017-04-01

Women still remain underrepresented in many areas of the geosciences, and this underrepresentation often begins early in their university career. In 2015, an interdisciplinary team including expertise in the geosciences (multiple sub-disciplines), psychology, education and STEM persistence began a project focused on understanding whether mentoring can increase the interest, persistence, and achievement of undergraduate women in geoscience fields. The developed program (PROGRESS) focuses on mentoring undergraduate female students, starting in their 1st and 2nd year, from two geographically disparate areas of the United States: the Carolinas in the southeastern part of the United States and the Front Range of the Rocky Mountains in the western part of the United States. The two regions were chosen due to their different student demographics, as well as the differences in the number of working female geoscientists in the region. The mentoring program includes a weekend workshop, access to professional women across geoscience fields, and both in-person and virtual peer networks. Four cohorts of students were recruited and participated in our professional development workshops (88 participants in Fall 2015 and 94 participants in Fall 2016). Components of the workshops included perceptions of the geosciences, women in STEM misconceptions, identifying personal strengths, coping strategies, and skills on building their own personal network. The web-platform (http://geosciencewomen.org/), designed to enable peer-mentoring and provide resources, was launched in the fall of 2015 and is used by both cohorts in conjunction with social media platforms. We will present an overview of the major components of the program, discuss lessons learned during 2015 that were applied to 2016, and share preliminary analyses of surveys and interviews with study participants from the first two years of a five-year longitudinal study that follows PROGRESS participants and a control group.

Field research internships: Why they impact students' decisions to major in the geosciences

NASA Astrophysics Data System (ADS)

Kortz, K. M.; Cardace, D.; Savage, B.; Rieger, D.

2017-12-01

Although internships have been shown to retain geoscience students, little research has been done on what components of research or field experiences during an internship impact students' decisions to major in the geosciences. We created and led a short, two-week field-based internship for 5 introductory-level students to conduct research and create a poster to present their results. In addition to the two professors leading the internship and the 5 interns, there were 2 masters students and 1 community college student who were returning to the field area to collect data for their own projects. These students also helped to guide and mentor the interns. The interns were diverse in many aspects: 3 were female, 2 were non-white, 3 were community college students (1 4YC student was a transfer), 2 were first-generation college students, and their ages ranged from 18 to 33. Based on our evaluation, we found that the research experience increased students' self-efficacy in the geosciences through various means, increased their connection with mentors and other individuals who could serve as resources, gave them a sense of belonging to the geoscience culture, increased their knowledge of geoscience career paths and expectations, helped them make connections with Earth, and maintained their interest. These factors have been described in the literature as leading to retention, and we propose that field-based internships are successful for recruitment or retention in the geosciences because they influence so many of these affective and cognitive components at once. In particular, the social aspect of internships plays a fundamental role in their success because many of these factors require close and sustained interactions with other people. An implication of this research is that these affective components, including social ones, should be explicitly considered in the design and implementation of internships to best serve as a recruitment and retention strategy.

Future Employment Opportunities for US Geoscience Graduates - a View From Historical Trends

NASA Astrophysics Data System (ADS)

Keane, C. M.; Milling, M. E.

2005-12-01

The geosciences in the United States has experienced a number of major booms and busts, but today has become, as a discipline, less dependent on the immediate fortunes of the natural resources industries. However, the actual employment distribution has not changed substantially in the last fifteen years, with the petroleum industry remaining by and far the single largest employer of geoscientists in the United States, and even more as a level of contributing to GNP. However, most of the geoscience professional ranks in industry were filled prior to and during the last major boom which ended in 1986. Most of this workforce is now heading into retirement and though total geoscience workforce demand is not likely to grow; substantial employment opportunities do and will exist as these individuals retire. However, this picture is more complicated than in the past. Most industries, both the traditional geoscience employers, such as petroleum, mining, and environment, and non-traditional, such as telecommunications, are increasingly global in their operations and perspectives. This increasing globalization means that US graduates now compete not only against graduates from other schools in the US, but throughout the world. When coupled with preferences for not hiring people in as expatriates for overseas assignment, US graduates face an increasingly competitive, but rewarding job market. The proverbial leveling of the playing field is also seen in the rapid rise in international membership of traditionally American professional and scientific societies. This internationalization is hardly discouraged within the culture of science, and is one that US students will need to embrace to compete effectively in the future for employment in the geosciences. One major change that will be necessitated is the adjustment of parts of academia to the new realities of preparing students for future employment within the discipline. Currently most US geoscience graduate programs are geared towards training students for the professoriate (of which new job opportunities are slower in coming than the private sector.) In particular, there are a suite of skill sets that geoscience programs could introduce into their curriculum to improve the competitiveness of their graduates.

Out of Boom and Bust, but Where to now for Geoscience Departments?

NASA Astrophysics Data System (ADS)

Keane, C. M.

2005-12-01

For most of the last 50 years, the fortunes of geoscience programs at the university level have waxed and waned with the health of the natural resources industries. These industries, and petroleum in particular, have experience major boom and bust cycles, of which geoscience programs often mirrored. This relationship began to change in the early 1990's when many geosciences programs began to offer environmental concentrations. This shift only lasted about five years before job opportunities began to decline in that field as well. By the mid 1990s, for the first time, the fortunes of geoscience departments began to mirror the overall trend of the other physical sciences - and just at the wrong time. The dot-com boom put negative pressure on enrollments, but since 2001, the geosciences, like many sciences, have now begun to experience 4-6 percent enrollment growth each year. Through all of this a number of departments have largely remained strong, and continue to grow. The trends of growth through the past twenty-five years gives us some insight into what healthy departments are doing right, and what opportunities exist for future growth for all programs. Two aspects of successful programs of particular note are those that retained strong, core basic geology academic programs, and those that continue to actively produce master's students. In particular, the master's level poses a unique opportunity for departmental growth. In other science disciplines, combined science master's with MBA's are generating substantial revenue for schools and enhancing the science program's status within the university community and the potential employer pool. However, though the number of master's degrees awarded in the geosciences has remained relatively steady, the number of schools that are actually awarding degrees has shrunk substantially, with the historically strong departments producing a large proportion of master's recipients. The challenge is to now 'read the tea leaves' of what future department success will require in an era of largely replacement-level hiring in the traditional geoscience job sectors and continuing shrinking federal research support. Recent departmental successes point to what appears to be paths for strong a strong future.

The Non-traditional Student, a new Geoscience Resource

NASA Astrophysics Data System (ADS)

Ferrell, R.; Anderson, L.; Bart, P.; Lorenzo, J. M.; Tomkin, J.

2004-12-01

The LSU GAEMP (Geoscience Alliance to Enhance Minority Participation) program targets non-traditional students, those without an undergraduate degree in geoscience, in its efforts to attract African American and Hispanic students from minority serving institutions (MSIs) to pursue careers in geology and geophysics. Faculty collaborators at nine MSIs (seven HBCUs and two HSIs) work closely with LSU faculty to advertise the program and to select student participants. The enthusiastic cooperation of the MSI Professors is crucial to success. The ideal student is a junior-level, high academic achiever with a major in one of the basic sciences, mathematics, engineering or computer science. A special summer course uses a focus on research to introduce basic geoscience concepts. Students are encouraged to design a cooperative research project to complete during their last year at their home institution and to apply for GAEMP graduate fellowships leading directly to an M.S. or Ph.D. in Geoscience. There are several reasons for the emphasis on these students 1. They have special knowledge and skills to use in graduate programs in geophysics, geochemistry, geobiology, etc. 2. Third-year students have demonstrated their ability to succeed in the academic world and are ready to select a graduate program that will enhance their employment prospects. 3. The MSIs, especially some of the physics programs at the collaborating HBCUs, provide well-trained, highly motivated graduates who have compiled excellent records in highly ranked graduate programs. This pool of talent is not available in the geosciences because most MSIs do not have geoscience degree programs. 4. This group provides a unique niche for focus as there are many programs concentrating on K-12 students and the recruitment of traditional majors. In the first year of GAEMP, 12 students participated in the summer program, six elected to pursue research projects and expressed interest in applying for the fellowships, and one student entered the graduate program early. The paucity of information regarding career opportunities and rewards in geoscience is one of the major obstacles encountered. GAEMP is sponsored by a 5-year NSF award through the OEDG program

Diversifying Geoscience by Preparing Faculty as Workshop Leaders to Promote Inclusive Teaching and Inclusive Geoscience Departments

NASA Astrophysics Data System (ADS)

Macdonald, H.; Manduca, C. A.; Beane, R. J.; Doser, D. I.; Ebanks, S. C.; Hodder, J.; McDaris, J. R.; Ormand, C. J.

2017-12-01

Efforts to broaden participation in the geosciences require that faculty implement inclusive practices in their teaching and their departments. Two national projects are building the capacity for faculty and departments to implement inclusive practices. The NAGT/InTeGrate Traveling Workshops Program (TWP) and the Supporting and Advancing Geoscience Education in Two-Year Colleges (SAGE 2YC) project each prepares a cadre of geoscience educators to lead workshops that provide opportunities for faculty and departments across the country to enhance their abilities to implement inclusive teaching practices and develop inclusive environments with the goal of increasing diversity in the geosciences. Both projects prepare faculty to design and lead interactive workshops that build on the research base, emphasize practical applications and strategies, enable participants to share their knowledge and experience, and include time for reflection and action planning. The curriculum common to both projects includes a framework of support for the whole student, supporting all students, data on diversity in the geosciences, and evidence-based strategies for inclusive teaching and developing inclusive environments that faculty and departments can implement. Other workshop topics include classroom strategies for engaging all students, addressing implicit bias and stereotype threat, and attracting diverse students to departments or programs and helping them thrive. Online resources for each project provide support beyond the workshops. The TWP brings together educators from different institutional types and experiences to develop materials and design a workshop offered to departments and organizations nationwide that request the workshop; the workshop leaders then customize the workshop for that audience. In SAGE 2YC, a team of leaders used relevant literature to develop workshop materials intended for re-use, and designed a workshop session for SAGE 2YC Faculty Change Agents, who then incorporate aspects of the session in workshops they lead for their regional faculty networks. Both projects prepare faculty to lead workshops on inclusive practices and programs as a strategy to diversify the geosciences by pervasively changing the way that faculty and departments support students.

Pedagogies in Action: A Community Resource Linking Teaching Methods to Examples of their Use

NASA Astrophysics Data System (ADS)

Manduca, C. A.; Fox, S. P.; Iverson, E. A.; Kirk, K.; Ormand, C. J.

2009-12-01

The Pedagogies in Action portal (http://serc.carleton.edu/sp) provides access to information on more than 40 teaching methods with examples of their use in geoscience and beyond. Each method is described with pages addressing what the method is, why or when it is useful, and how it can be implemented. New methods added this year include Teaching with Google Earth, Jigsaw, Teaching the Process of Science, Guided Discovery Problems, Teaching Urban Students, and Using ConceptTests. Examples then show specifically how the method has been used to teach concepts in a variety of disciplines. The example collection now includes 775 teaching activities of which more than 550 are drawn from the geosciences. Geoscience faculty are invited to add their own examples to this collection or to test examples in the collection and provide a review. Evaluation results show that the combination of modules and activities inspires teachers at all levels to use a new pedagogy and increases their confidence that they can use it successfully. In addition, submitting activities to the collection, including writing summary information for other instructors, helps them think more carefully about the design of their activity. The activity collections are used both for ready to use activities and to find ideas for new activities. The portal provides overarching access to materials developed by a wide variety of collaborating partners each of which uses the service to create a customized pedagogic portal addressing a more specific audience. Of interest to AGU members are pedagogic portals on Starting Point: Teaching Introductory Geoscience (http://serc.carleton.edu/introgeo); On the Cutting Edge (http://serc.carleton.edu/NAGTWorkshops); Enduring Resources for Earth System Education (http://earthref.org/ERESE) Microbial Life Educational Resources (http://serc.carleton.edu/microbe_life); the National Numeracy Network (http://serc.carleton.edu/nnn/index.html); CAUSE: The Consortium for Undergraduate Statistics Education (http://causeweb.org); ComPADRE: Digital Resources for Physics and Astronomy Education (http://www.compadre.org) and Project Kaleidoscope (http://pkal.org). Pedagogies in Action is part of the National Science Digital Library (http://nsdl.org). Projects or groups interested in exploring use of the service can find information about using the service on the project website or contact the authors.

Online, interactive assessment of geothermal energy potential in the U.S

NASA Astrophysics Data System (ADS)

Allison, M. L.; Richard, S. M.; Clark, R.; Coleman, C.; Love, D.; Pape, E.; Musil, L.

2011-12-01

Geothermal-relevant geosciences data from all 50 states (www.stategeothermaldata.org), federal agencies, national labs, and academic centers are being digitized and linked in a distributed network via the U.S. Department of Energy-funded National Geothermal Data System (NGDS) to foster geothermal energy exploration and development through use of interactive online 'mashups,' data integration, and applications. Emphasis is first to make as much information as possible accessible, with a long range goal to make data interoperable through standardized services and interchange formats. Resources may be made available as documents (files) in whatever format they are currently in, converted to tabular files using standard content models, or published as Open Geospatial Consortium or ESRI Web services using the standard xml schema. An initial set of thirty geoscience data content models are in use or under development to define standardized interchange format: aqueous chemistry, borehole temperature data, direct use feature, drill stem test, earthquake hypocenter, fault feature, geologic contact feature, geologic unit feature, thermal/hot spring description, metadata, quaternary fault, volcanic vent description, well header feature, borehole lithology log, crustal stress, gravity, heat flow/temperature gradient, permeability, and feature description data like developed geothermal systems, geologic unit geothermal properties, permeability, production data, rock alteration description, rock chemistry, and thermal conductivity. Map services are also being developed for isopach maps (depth to bedrock), aquifer temperature maps, and several states are working on geothermal resource overview maps. Content models are developed preferentially from existing community use in order to encourage widespread adoption and promulgate minimum metadata quality standards. Geoscience data and maps from NGDS participating institutions (USGS, Southern Methodist University, Boise State University Geothermal Data Coalition) are being supplemented with extensive land management and land use resources from the Western Regional Partnership (15 federal agencies and 5 Western states) to provide access to a comprehensive, holistic set of data critical to geothermal energy development. As of August 2011, over 33,000 data resources have been registered in the system catalog, along with scores of Web services to deliver integrated data to the desktop for free downloading or online use. The data exchange mechanism is built on the U.S. Geoscience Information Network (USGIN, http://lab.usgin.org) protocols and standards developed in partnership with the U.S. Geological Survey.

Inter-Tribal Student Services (I.S.S.): Collaborative Action Education in Building and Guiding the Future Under-represented Geosciences Workforce Through Tribal Foundations, Mentorship and Professional Development.

NASA Astrophysics Data System (ADS)

Bolman, J.

2015-12-01

Inter-Tribal Student Services (I.S.S.) was created as an Indian Self-Determination Organization to meet the every growing Tribal and under-represented minorities (URM) geosciences workforce needs. I.S.S. is one of only a few Indian Self-Determined Organizations in the U.S. with a distinct focused on buidling the Tribal and URM geosciences and natural resources workforces. In past three years, I.S.S has worked in partnership with U.S. colleges/universities, state/federal agencies (Bureau of Indian Affairs), private and International organizations and most importantly U.S. Tribal Nations to ensure emerging high school students, undergraduates, graduate students and post doctorates have the opportunities for training in supportive and unique environments, navigational mentoring, and broad professional development to build and practice the skills required for blue-collar, scientific, and managerial positions. I.S.S. has been highly successful in filling workforce opportunities within the broad range of geosciences positions. I.S.S. students are proficient in understanding and maneuvering the complex landscapes of interdisciplinary research, multidisciplinary multi-partner projects, traditional/western philosophies as well as being highly proficient in all areas of problem solving and communications. Research and on-site projects have heightened the educational experiences of all participants, in addition to addressing a perplexing geosciences challenge grounded in a Tribal environment. A number of the I.S.S. participants and students have found geosciences positions in Tribes, state/federal agencies, enterprize as well as International organizations. I.S.S. practices and has infused all research and projects with intergenerational teaching/learning, participation solution-focused initiatives, and holistic/multicultural mentoring. The presentation will highlight the vision, design, implementation, outcomes and future directions of I.S.S and participants.

From Churches to Pavements: Urban Geology and Paleontology in Algarve

NASA Astrophysics Data System (ADS)

Azevedo Rodrigues, Luis

2015-04-01

Urban environments were and are tremendous consumers of geologic resources, offering excellent places for Geosciences outreach activities. Since 2011, three distinct science outreach activities were planned, produced and performed in three Algarve cities - Faro (GeoStories of Faro's Downtown), Lagos (Geology at the Corner) and Tavira (From the Museum to the Convent). Urban structures - churches, monuments, buildings and urban equipments were the starting point of the geological and paleontological stories that constitute the core of these informal education visits which also combine Art History and Heritage aspects. The urban buildings were the narrative tool to these Geosciences stories being the characters the rocks and/or the fossils as well as the city itself. Beyond the natural science element, the analyzed objects have relevant esthetical, historical or symbolic dimensions, conferring this way two levels of interpretation to the stories: the geosciences level; the other, the Historical and Architectural Heritage. The nineteen visits had 350 participants - Tavira (6; 100), Faro (4; 70) e Lagos (9; 180). Promoting and contribute to the Geosciences (Geology and Paleontology) outreach was the main objective of these walks, as well as: - modify the way that the general population looks at urban buildings; - contribute to the informal education of a general public especially among the public which is interested in Architecture, History and Heritage; - integrate different areas of human knowledge - Geosciences and Architecture, History and Heritage. The visits were tested and implemented and presently constitute one of the science outreach activities of the Ciência Viva Centers in the Algarve. As a result of these visits three bilingual books (Portuguese and English) of the Geosciences walks were edited. The guides, with 120 pages each, focus on the geological and paleontological characteristics of the visited places as well as the art history framework of the different monuments and urban areas.

Increasing student success in STEM through geosciences based GIS curriculum, interdisciplinary project based learning, and specialized STEM student services

NASA Astrophysics Data System (ADS)

Cheung, W.

2012-12-01

Under the auspices of the National Science Foundation's Advanced Technological Education Grant and the Department of Education's Title V/HSI Grant, Palomar College students from a variety of disciplines have not only been exposed to the high growth field of geospatial technologies, but have also been exposed to the geosciences and regional environmental issues in their GIS courses. By integrating introductory Physical Geography topics such as liquefaction, subsidence, ozone depletion, plate tectonics, and coastal processes in the introductory GIS curriculum, GIS students from fields ranging from Archaeology to Zoology were exposed to basic geosciences theories in a series of hands-on interactive exercises, while gaining competency in geospatial technologies. Additionally, as students undertake interdisciplinary service learning projects under the supervision of experts in the private, governmental, and nonprofit sectors, students were introduced to the STEM workplace, forged invaluable professional connections, applied their classroom knowledge to advance research (e.g. analyzing migration patterns of cephalopod), and analyzed regional environmental issues (e.g. distribution of invasive plants in state natural preserves). In order to further the retention and completion of students in GIS, Earth Science, and other STEM courses, a STEM Student Learning Center was constructed, whereby students can receive services such as supplemental instruction, walk-in tutoring, STEM counseling and transfer advising, as well as faculty and peer mentoring.

New Center Links Earth, Space, and Information Sciences

NASA Astrophysics Data System (ADS)

Aswathanarayana, U.

2004-05-01

Broad-based geoscience instruction melding the Earth, space, and information technology sciences has been identified as an effective way to take advantage of the new jobs created by technological innovations in natural resources management. Based on this paradigm, the University of Hyderabad in India is developing a Centre of Earth and Space Sciences that will be linked to the university's super-computing facility. The proposed center will provide the basic science underpinnings for the Earth, space, and information technology sciences; develop new methodologies for the utilization of natural resources such as water, soils, sediments, minerals, and biota; mitigate the adverse consequences of natural hazards; and design innovative ways of incorporating scientific information into the legislative and administrative processes. For these reasons, the ethos and the innovatively designed management structure of the center would be of particular relevance to the developing countries. India holds 17% of the world's human population, and 30% of its farm animals, but only about 2% of the planet's water resources. Water will hence constitute the core concern of the center, because ecologically sustainable, socially equitable, and economically viable management of water resources of the country holds the key to the quality of life (drinking water, sanitation, and health), food security, and industrial development of the country. The center will be focused on interdisciplinary basic and pure applied research that is relevant to the practical needs of India as a developing country. These include, for example, climate prediction, since India is heavily dependent on the monsoon system, and satellite remote sensing of soil moisture, since agriculture is still a principal source of livelihood in India. The center will perform research and development in areas such as data assimilation and validation, and identification of new sensors to be mounted on the Indian meteorological satellites to make measurements in those spectral bands and with those polarizations that are needed to address water resources management issues.

GIRAF 2009 - Taking action on geoscience information across Africa

NASA Astrophysics Data System (ADS)

Asch, Kristine

2010-05-01

A workshop in Windhoek Between 16 and 20 March 2009 97 participants from 26 African nations, plus four European countries, and representatives from UNESCO, ICSU and IUGS-CGI, held a workshop at the Namibian Geological Survey in Windhoek. The workshop - GIRAF 2009 - Geoscience InfoRmation In Africa - was organised by the Federal Institute for Geosciences and Natural Resources (BGR) and the Geological Survey of Namibia (GSN) at the Namibian Ministry for Mines and Energy and was mainly financed by the German Federal Ministry for Economic Cooperation and Development (BMZ), supported by the IUGS Commission for the Management and Application of Geoscience Information (CGI). The participants came to Namibia to discuss one of the most topical issues in the geological domain - geoscience information and informatics. A prime objective was to set up a pan-African network for exchanging knowledge about geoscience information. GIRAF 2009 builds on the results of a preparatory workshop organised by the CGI and funded by the IUGS, which was held in June 2006 in Maputo at the 21st Colloquium on African Geology - CAG21. This preparatory workshop concentrated on identifying general problems and needs of African geological institutions in discussion with representatives of African geological surveys, universities, private companies and non-governmental organisations. The GIRAF 2009 workshop used the results of this discussion to plan and design its programme Aims In detail the five aims of the GIRAF2009 workshop were: to bring together relevant African authorities, national experts and stakeholders in geoscience information; to initiate the building of a pan-African geoscience information knowledge network to exchange and share geoscience information knowledge and best practice; to integrate the authorities, national experts and experts across Africa into global geoinformation initiatives; to develop a strategic plan for Africa's future in geoscience information; to make Africa a more active part of the international geoscience information community. The programme for the GIRAF 2009 workshop was designed to explore each of these aspects to improve the way geoscience information contributes to improve the health and prosperity of the people in Africa. The Programme The aim of the week wasto better understand the reality of the status of geoscience information management, delivery, and systems from the perspective of the practitioners across Africa. To do that, in addition to VIP welcome speeches and presentations from across the continent, the programme included two sets of breakout sessions allowing more detailed discussion of specific issues, and each day, a novel "Question of the day", where individual feedback was sought on three pointed questions. These exercises ensured that everyone was able to contribute their views and experiences. The conclusion - a 15 point GIRAF 2009 Strategy and Agreement The results were intense discussion of the issues which the participants felt were key to developing and improving the way geoscience information could be managed and delivered in Africa. The very tangible outcome of a hardworking but fruitful week was the unanimous endorsement of a series of fifteen practical recommendations - the GIRAF Strategy and Agreement. Our week together provided new and valuable experience and new contacts, networks and friendships and most importantly the base for a sustainable initiative to improve the way geoscience information will be managed and delivered in Africa. We now look forward and are working on to taking those important recommendations forward.

The YES Africa 2011 Symposium: A Key to Developing the Future Geoscience Workforce in Africa

NASA Astrophysics Data System (ADS)

Nkhonjera, E.

2011-12-01

Africa is facing serious challenges in geoscience education. This has been as a result of absence of or very young/small Earth Science Departments in some universities (e.g., Mauritius, Namibia, Botswana, Swaziland, Malawi): Limited capacity (staff and equipment needed for practicals) to cope with the growing number of students, compounded by brain drain of academic staffs and the fact that current tertiary programmes do not seem to produce graduates suitable for the industry are some of the contributing factors to the challenges, (UNESCO-AEON Report, 2009). As such Earth Science studies in Africa have been one of the career paths that has not been promoted or highly preferred by many students. In January 2011, the YES Network African chapter was launched through the YES Africa 2011 Symposium that took place at the University of Johannesburg South Africa in Conjunction with the 23rd Colloquium of Africa Geology from the 08-14th January 2011. The YES Africa 2011 Symposium was organized by five YES African National networks from Southern, Central, Eastern and Northern Africa to bring young geoscientists from all regions of Africa together to present their research about African geoscience topics. The symposium also included roundtable discussions about increasing the involvement of youth's participation in geoscience issues in Africa, about how to increase the number of youths in African geosciences education university programs, and about how to promote geoscience careers to university students in Africa c. Roundtable discussions revealed that many African colleges and universities do not provide adequate infrastructure and resources to support the students studying in the department. As such, most students graduate with poor preparation for geoscience careers, having gained a theoretical understanding of geology, but not the practical application of the discipline. The recommendations from the YES Africa 2011 Symposium also highlighted on the best ways of developing the geoscience workforce in Africa so that it can become competitive within the international community. International networks like the YES Network help geoscience students and early-career geoscientists to interact with their colleagues around the world and share knowledge and experiences. YES Network conferences, such as the YES Africa 2011 Symposium are a prime example of how geoscience students and early-career geoscientists are actively working together through this professional international network to provide opportunities for young scientists to present their research, share ideas about future projects, and discuss strategies for solving current scientific and career or academic pathway concerns.

Geoscience and the 21st Century Workforce

NASA Astrophysics Data System (ADS)

Manduca, C. A.; Bralower, T. J.; Blockstein, D.; Keane, C. M.; Kirk, K. B.; Schejbal, D.; Wilson, C. E.

2013-12-01

Geoscience knowledge and skills play new roles in the workforce as our society addresses the challenges of living safely and sustainably on Earth. As a result, we expect a wider range of future career opportunities for students with education in the geosciences and related fields. A workshop offered by the InTeGrate STEP Center on 'Geoscience and the 21st Century Workforce' brought together representatives from 24 programs with a substantial geoscience component, representatives from different employment sectors, and workforce scholars to explore the intersections between geoscience education and employment. As has been reported elsewhere, employment in energy, environmental and extractive sectors for geoscientists with core geology, quantitative and communication skills is expected to be robust over the next decade as demand for resources grow and a significant part of the current workforce retires. Relatively little is known about employment opportunities in emerging areas such as green energy or sustainability consulting. Employers at the workshop from all sectors are seeking the combination of strong technical, quantitative, communication, time management, and critical thinking skills. The specific technical skills are highly specific to the employer and employment needs. Thus there is not a single answer to the question 'What skills make a student employable?'. Employers at this workshop emphasized the value of data analysis, quantitative, and problem solving skills over broad awareness of policy issues. Employers value the ability to articulate an appropriate, effective, creative solution to problems. Employers are also very interested in enthusiasm and drive. Participants felt that the learning outcomes that their programs have in place were in line with the needs expressed by employers. Preparing students for the workforce requires attention to professional skills, as well as to the skills needed to identify career pathways and land a job. This critical work takes place both inside and outside of the classroom and occurs as a progression throughout the course of study. Professional skills were recognized as an area where outcomes could be strengthened. The challenge faced by geoscience programs is developing pathways into the workforce for students who bring different skills and interests to their studies. Workforce data suggest that in the past only 30% of undergraduate graduates have remained in the geosciences indicating that geoscience programs are playing an important role in developing the workforce beyond the geosciences. A collection of program descriptions describes what is known about career pathways from the programs represented at the workshop.

Undergraduate Research in Geoscience with Students from Two-year Colleges: SAGE 2YC Resources

NASA Astrophysics Data System (ADS)

McDaris, J. R.; Hodder, J.; Macdonald, H.; Baer, E. M.; Blodgett, R. H.

2014-12-01

Undergraduate research experiences are important for the development of expertise in geoscience disciplines. These experiences have been shown to help students learn content and skills, promote students' cognitive and affective development, and develop students' sense of self. Early exposure to research experiences has shown to be effective in the recruitment of students, improved retention and persistence in degree programs, motivation for students to learn and increase self-efficacy, improved attitudes and values about science, and overall increased student success. Just as departments at four-year institutions (4YCs) are increasingly integrating research into their introductory courses, two-year college (2YC) geoscience faculty have a great opportunity to ground their students in authentic research. The Undergraduate Research with Two-year College Students website developed by SAGE 2YC: Supporting and Advancing Geoscience Education at Two-year Colleges provides ideas and advice for 2YC and 4YC faculty who want to get more 2YC students involved in research. The continuum of possibilities for faculty to explore includes things that can be done at 2YCs (eg. doing research as part of a regular course, developing a course specifically around research on a particular topic, or independent study), done in collaboration with other local institutions (eg. using their facilities, conducting joint class research, or using research to support transfer programs), and by involving students in the kind of organized Undergraduate Research programs run by a number of institutions and organizations. The website includes profiles illustrating how 2YC geoscience faculty have tackled these various models of research and addressed potential challenges such as lack of time, space, and funding as part of supporting the wide diversity of students that attend 2YCs, most of whom have less experience than that of rising seniors who are the traditional REU participant. The website also provides resources on effective strategies for developing REU programs for community college students, examples of successful multi-year programs, links to other projects working on undergraduate research in the first two years, and references for further reading. serc.carleton.edu/sage2yc/studentsuccess/ug-research/

Data Immersion for CCNY Undergraduate Summer Interns at the IEDA Geoinformatics Facility

NASA Astrophysics Data System (ADS)

Uribe, R.; Van Wert, T.; Alabi, T.

2016-12-01

National Science Foundation (NSF) funded programs that provide grants and resources to enhance undergraduate learning and provide a pathway to future career opportunities in the geosciences by increasing retention and broadening participation. In an increasingly digital world, geoinformatics and the importance of large data storage and accessibility is a rapidly expanding field in the geosciences. The NSF-funded Interdisciplinary Earth Data Alliance (IEDA) - City College of New York (CCNY) summer internship program aims to provide diverse undergraduates from CCNY with data processing experience within the IEDA facility at Columbia University's Lamont-Doherty Earth Observatory (LDEO). CCNY interns worked alongside IEDA mentors and were immersed in the day-to-day operations of the IEDA facility. Skills necessary to work with geoscience data were developed throughout the internship and participation with the broader cohort of Lamont summer interns was promoted. Summer lectures delivered by researchers at LDEO provided interns with cutting-edge geoscience content from experts across a wide range of fields in the Earth sciences. CCNY undergraduate interns undertook two data compilation projects. First, interns compiled LiDAR land elevation data to enhance the land-ocean base map used across IEDA map-based resources. For that, the interns downloaded and classified one- and three-meter resolution LiDAR topographic data from the USGS The National Mapfor the lower 48 states. Second, computer-derived regional and global seismic tomography models from the Incorporated Research Institutions for Seismology (IRIS) were compiled and processed for integration with GeoMapApp, a free mapping application developed at LDEO (www.geomapapp.org). Interns established a data processing workflow to extract tomographic depth slices from dozens of tomographic grids. Executing LINUX commands and shell scripts, the native format binary netCDF files were resampled and reformatted and compared to the published figures to check for consistency. The extracted tomographic slices will be included in GeoMapApp's user friendly map-based interface. The IEDA-CCNY internship encouraged students to develop and build basic skills necessary for the rigors of graduate study and real world geoscience career exposure.

OneGeology - The most appropriate model to achieve access to up-to-date geoscience data using a distributed data system

NASA Astrophysics Data System (ADS)

Komac, Marko; Duffy, Tim; Robida, Francois; Harrison, Matt; Allison, Lee

2015-04-01

OneGeology is an initiative of Geological Survey Organisations (GSO) around the globe that dates back to Brighton, UK in 2007. Since then OneGeology has been a leader in developing geological online map data using a new international standard - a geological exchange language known as the 'GeoSciML' (currently version 3.2 exists, which enables instant interoperability of the data). Increased use of this new language allows geological data to be shared and integrated across the planet with other organisations. One of very important goals of OneGeology was a transfer of valuable know-how to the developing world, hence shortening the digital learning curve. In autumn 2013 OneGeology was transformed into a Consortium with a clearly defined governance structure, making its structure more official, its operability more flexible and its membership more open where in addition to GSO also to other type of organisations that manage geoscience data can join and contribute. The next stage of the OneGeology initiative will hence be focused into increasing the openness and richness of that data from individual countries to create a multi-thematic global geological data resource on the rocks beneath our feet. Authoritative information on hazards and minerals will help to prevent natural disasters, explore for resources (water, minerals and energy) and identify risks to human health on a planetary scale. With this new stage also renewed OneGeology objectives were defined and these are 1) to be the provider of geosciences data globally, 2) to ensure exchange of know-how and skills so all can participate, and 3) to use the global profile of 1G to increase awareness of the geosciences and their relevance among professional and general public. We live in a digital world that enables prompt access to vast amounts of open access data. Understanding our world, the geology beneath our feet and environmental challenges related to geology calls for accessibility of geoscience data and OneGeology Portal (portal.onegeology.org) is the place to find them.

Multisource geological data mining and its utilization of uranium resources exploration

NASA Astrophysics Data System (ADS)

Zhang, Jie-lin

2009-10-01

Nuclear energy as one of clear energy sources takes important role in economic development in CHINA, and according to the national long term development strategy, many more nuclear powers will be built in next few years, so it is a great challenge for uranium resources exploration. Research and practice on mineral exploration demonstrates that utilizing the modern Earth Observe System (EOS) technology and developing new multi-source geological data mining methods are effective approaches to uranium deposits prospecting. Based on data mining and knowledge discovery technology, this paper uses multi-source geological data to character electromagnetic spectral, geophysical and spatial information of uranium mineralization factors, and provides the technical support for uranium prospecting integrating with field remote sensing geological survey. Multi-source geological data used in this paper include satellite hyperspectral image (Hyperion), high spatial resolution remote sensing data, uranium geological information, airborne radiometric data, aeromagnetic and gravity data, and related data mining methods have been developed, such as data fusion of optical data and Radarsat image, information integration of remote sensing and geophysical data, and so on. Based on above approaches, the multi-geoscience information of uranium mineralization factors including complex polystage rock mass, mineralization controlling faults and hydrothermal alterations have been identified, the metallogenic potential of uranium has been evaluated, and some predicting areas have been located.

Selected Sources on the Internet.

ERIC Educational Resources Information Center

Scott, Ralph Lee; And Others

1994-01-01

Five articles describe specific Internet resources, including geoscience and science databases; economic and statistical information; the JANET (Joint Academic Network) Bulletin Board for Librarians; and White House communications. A sixth article describes how practical applications of Internet information create new roles for reference…

Inventory of Innovative Learning Materials in Marine Science and Technology. UNESCO Reports in Marine Science 60.

ERIC Educational Resources Information Center

Richards, Adrian F.; Richards, Efrosine A.

The Inventory of Innovative Learning Materials in Marine Science and Technology includes 32 computer-, 148 video-, 16 film-, and 11 CD-ROM-based entries. They concern materials in biosciences (67), chemistry (5), geosciences (16), physics (23), technology (76) and other (20). This first, initial compilations is conceived as the basis for more…

Integrating iPad Technology in Earth Science K-12 Outreach Courses: Field and Classroom Applications

ERIC Educational Resources Information Center

Wallace, Davin J.; Witus, Alexandra E.

2013-01-01

Incorporating technology into courses is becoming a common practice in universities. However, in the geosciences, it is difficult to find technology that can easily be transferred between classroom- and field-based settings. The iPad is ideally suited to bridge this gap. Here, we fully integrate the iPad as an educational tool into two…

Alternative Evaluation Designs for Data-Centered Technology-Based Geoscience Education Projects

NASA Astrophysics Data System (ADS)

Zalles, D. R.

2012-12-01

This paper will present different strategies for how to evaluate contrasting K-12 geoscience classroom-based interventions with different goals, leveraging the first author's experiences as principal investigator of four NSF and NASA-funded geoscience education projects. Results will also be reported. Each project had its own distinctive features but all had in common the broad goal of bringing to high school classrooms uses of real place-based geospatial data to study the relationships of Earth system phenomena to climate change and sustainability. The first project's goal was to produce templates and exemplars for curriculum and assessment designs around studying contrasting geoscience topics with different data sets and forms of data representation. The project produced a near transfer performance assessment task in which students who studied climate trends in Phoenix turned their attention to climate in Chicago. The evaluation looked at the technical quality of the assessment instrument as measured by inter-rater reliability. It then analyzed the assessment results against student responses to the instructional tasks about Phoenix. The evaluation proved useful in pinpointing areas of student strength and weakness on different inquiry tasks, from simple map interpretation to analysis of contrasting claims about what the data indicate. The goal of the second project was to produce an exemplar curriculum unit that bridges Western science and traditional American Indian ecological knowledge for student learning and skill building about local environmental sustainability issues. The evaluation looked at the extent to which Western and traditional perspectives were incorporated into the design of the curriculum. The curriculum was not constructed with a separate assessment, yet evidence centered design was utilized to extrapolate from the exemplar unit templates for future instructional and assessment tasks around other places, other sustainability problems, and other repositories of traditional ecological knowledge. The goals of the two other projects, in progress, are to build forms of support and access by teachers to complex scientific geospatial data sets concerning climate change and a myriad of related Earth system phenomena for which measurements are available from different government agencies such as NASA, NCAR, and the USGS. The driving philosophy of these projects has been that teachers are more likely to use these powerful resources when provided with curricula and educative supports, yet have the option of implementing the curricula as written, adapting the curricula, or developing their own curricula provided that they on at least some of the data about the local region. These projects are being evaluated on the extent to which this model of flexible implementation is bearing fruit in teacher capacity building and student learning outcomes. Hence, teachers are being provided with a set of pre post assessment options that they can choose from, including for example selected response items on Earth system variables of their choice, map interpretation items, and open-ended constructed response items about the weather, climate, and ecosystem concepts that they select to focus on with their students. Teacher capacity building is being measured through oral and written documentation of the teachers' evolving learning about the data resources and evolving decision-making about how to use the resources.

Development of Visualizations and Loggable Activities for the Geosciences. Results from Recent TUES Sponsored Projects

NASA Astrophysics Data System (ADS)

De Paor, D. G.; Bailey, J. E.; Whitmeyer, S. J.

2012-12-01

Our TUES research centers on the role of digital data, visualizations, animations, and simulations in undergraduate geoscience education. Digital hardware (smartphones, tablets, GPSs, GigaPan robotic camera mounts, etc.) are revolutionizing field data collection. Software products (GIS, 3-D scanning and modeling programs, virtual globes, etc.) have truly transformed the way geoscientists teach, learn, and do research. Whilst Google-Earth-style visualizations are famously user-friend for the person browsing, they can be notoriously unfriendly for the content creator. Therefore, we developed tools to help educators create and share visualizations as easily as if posting on Facebook. Anyone whoIf you wish to display geological cross sections on Google Earth, go to digitalplanet.org, upload image files, position them on a line of section, and share with the world through our KMZ hosting service. Other tools facilitate screen overlay and 3-D map symbol generation. We advocate use of such technology to enable undergraduate students to 'publish' their first mapping efforts even while they are working in the field. A second outcome of our TUES projects merges Second-Life-style interaction with Google Earth. We created games in which students act as first responders for natural hazard mitigation, prospectors for natural resource explorations, and structural geologist for map-making. Students are represented by avatars and collaborate by exchange of text messages - the natural mode of communication for the current generation. Teachers view logs showing student movements as well as transcripts of text messages and can scaffold student learning and geofence students to prevent wandering. Early results of in-class testing show positive learning outcomes. The third aspect of our program emphasizes dissemination. Experience shows that great effort is required to overcome activation energy and ensure adoption of new technology into the curriculum. We organized a GSA Penrose Conference, a GSA Pardee Keynote Symposium, and AGU Townhall Meeting, and numerous workshops at annual and regional meetings, and set up a web site dedicated to dissemination of program products. Future plans include development of augmented reality teaching resources, hosting of community mapping services, and creation of a truly 4-D virtual globe.;

Automatic User Interface Generation for Visualizing Big Geoscience Data

NASA Astrophysics Data System (ADS)

Yu, H.; Wu, J.; Zhou, Y.; Tang, Z.; Kuo, K. S.

2016-12-01

Along with advanced computing and observation technologies, geoscience and its related fields have been generating a large amount of data at an unprecedented growth rate. Visualization becomes an increasingly attractive and feasible means for researchers to effectively and efficiently access and explore data to gain new understandings and discoveries. However, visualization has been challenging due to a lack of effective data models and visual representations to tackle the heterogeneity of geoscience data. We propose a new geoscience data visualization framework by leveraging the interface automata theory to automatically generate user interface (UI). Our study has the following three main contributions. First, geoscience data has its unique hierarchy data structure and complex formats, and therefore it is relatively easy for users to get lost or confused during their exploration of the data. By applying interface automata model to the UI design, users can be clearly guided to find the exact visualization and analysis that they want. In addition, from a development perspective, interface automaton is also easier to understand than conditional statements, which can simplify the development process. Second, it is common that geoscience data has discontinuity in its hierarchy structure. The application of interface automata can prevent users from suffering automation surprises, and enhance user experience. Third, for supporting a variety of different data visualization and analysis, our design with interface automata could also make applications become extendable in that a new visualization function or a new data group could be easily added to an existing application, which reduces the overhead of maintenance significantly. We demonstrate the effectiveness of our framework using real-world applications.

EarthCube - A Community-led, Interdisciplinary Collaboration for Geoscience Cyberinfrastructure

NASA Astrophysics Data System (ADS)

Dick, Cindy; Allison, Lee

2016-04-01

The US NSF EarthCube Test Enterprise Governance Project completed its initial two-year long process to engage the community and test a demonstration governing organization with the goal of facilitating a community-led process on designing and developing a geoscience cyberinfrastructure. Conclusions are that EarthCube is viable, has engaged a broad spectrum of end-users and contributors, and has begun to foster a sense of urgency around the importance of open and shared data. Levels of trust among participants are growing. At the same time, the active participants in EarthCube represent a very small sub-set of the larger population of geoscientists. Results from Stage I of this project have impacted NSF decisions on the direction of the EarthCube program. The overall tone of EarthCube events has had a constructive, problem-solving orientation. The technical and organizational elements of EarthCube are poised to support a functional infrastructure for the geosciences community. The process for establishing shared technological standards has notable progress but there is a continuing need to expand technological and cultural alignment. Increasing emphasis is being given to the interdependencies among EarthCube funded projects. The newly developed EarthCube Technology Plan highlights important progress in this area by five working groups focusing on: 1. Use cases; 2. Funded project gap analysis; 3. Testbed development; 4. Standards; and 5. Architecture. The EarthCube governance implementing processes to facilitate community convergence on a system architecture, which is expected to emerge naturally from a set of data principles, user requirements, science drivers, technology capabilities, and domain needs.

AGU scientists urge Congress to invest in research and science education

NASA Astrophysics Data System (ADS)

Rothacker, Catherine

2012-10-01

With the "fiscal cliff" of sequestration drawing closer and threatening to hit basic science research funding with an 8.2% cut, according to an estimate by the Office of Management and Budget, congressional compromise on a budget plan is more urgent than ever. To discuss the value of scientific research and education with their senators and representatives, 55 Earth and space scientists from 17 states came to Washington, D. C., on 11-12 September to participate in the fifth annual Geosciences Congressional Visits Day sponsored by AGU and six other geoscience organizations. Although their specialties varied from space weather to soil science, the scientists engaged members of Congress and their staff in a total of 116 meetings to discuss a common goal: securing continued, steady investment in the basic scientific research that allows scientists to monitor natural hazards, manage water and energy resources, and develop technologies that spur economic growth and job creation. To make the most of these visits on 12 September, participants attended a training session the previous day, during which they learned about the details of the policy- making process and current legislative developments and practiced conducting a congressional meeting. Congressional Science Fellows, including past AGU fellow Rebecca French, described their experiences as scientists working on Capitol Hill, and White House policy analyst Bess Evans discussed the president's stance on sequestration and funding scientific research.

Workforce Preparation - A Breakout Session for the Building Strong Geoscience Departments Visiting Workshop Program

NASA Astrophysics Data System (ADS)

Doser, D. I.

2009-12-01

We have designed a workshop breakout session and accompanying web based materials to assist geoscience departments in better preparing their students for professional careers following graduation. The session explores ways to obtain feedback about career preparation from employers and alumni that can be used to develop more effective curriculum, as well as departmental activities to better prepare students for employment opportunities. In addition, it identifies sources outside a department that can be used in the workforce preparation process and methods to assess any changes implemented to prepare students for the workforce. Concrete examples include feedback from a survey of recent (< 5 years) alumni at the University of Texas at El Paso, student run research meetings with built-in assessment opportunities, and a wealth of on-line resources. The session was initially tested in June 2009 at the Strengthening Your Strong Geoscience Department workshop. Comments from the June participants have been used to improve the session for the 2009-2010 “visiting workshop” program.

Gender differences in recommendation letters for postdoctoral fellowships in geoscience

NASA Astrophysics Data System (ADS)

Dutt, Kuheli; Pfaff, Danielle L.; Bernstein, Ariel F.; Dillard, Joseph S.; Block, Caryn J.

2016-11-01

Gender disparities in the fields of science, technology, engineering and mathematics, including the geosciences, are well documented and widely discussed. In the geosciences, despite receiving 40% of doctoral degrees, women hold less than 10% of full professorial positions. A significant leak in the pipeline occurs during postdoctoral years, so biases embedded in postdoctoral processes, such as biases in recommendation letters, may be deterrents to careers in geoscience for women. Here we present an analysis of an international data set of 1,224 recommendation letters, submitted by recommenders from 54 countries, for postdoctoral fellowships in the geosciences over the period 2007-2012. We examine the relationship between applicant gender and two outcomes of interest: letter length and letter tone. Our results reveal that female applicants are only half as likely to receive excellent letters versus good letters compared to male applicants. We also find no evidence that male and female recommenders differ in their likelihood to write stronger letters for male applicants over female applicants. Our analysis also reveals significant regional differences in letter length, with letters from the Americas being significantly longer than any other region, whereas letter tone appears to be distributed equivalently across all world regions. These results suggest that women are significantly less likely to receive excellent recommendation letters than their male counterparts at a critical juncture in their career.

Geoscientists Flock to Capitol Hill for Congressional Visits Day

NASA Astrophysics Data System (ADS)

Chell, Kaitlin

2009-10-01

The second annual Geosciences Congressional Visits Day (Geo-CVD), on 15-16 September 2009, came at a time when the U.S. Congress is considering a number of issues intimately connected to the geosciences, including energy, the environment, and climate. Nearly 60 geoscientists from across the country, including 22 AGU members from 12 states, participated in this year's event by discussing geoscience issues with members of Congress and their staffs. AGU cosponsored the event along with nine other Earth and space science societies that work together on geoscience policy issues as part of the Geopolicy Working Group in Washington, D. C. Geo-CVD kicked off with the U.S. Geological Survey (USGS) Coalition's annual reception on Capitol Hill on 14 September. AGU is a member of the USGS Coalition, which includes several other science societies, and this year AGU organized the reception together with the Seismological Society of America. At the reception, U.S. senators Dianne Feinstein (D-Calif.) and Lisa Murkowski (R-Alaska) received the coalition's annual Leadership Award in recognition of their continuing commitment to USGS. Sen. Feinstein chairs the Senate Appropriations Subcommittee on Interior, Environment, and Related Issues, which is tasked with allocating funds to USGS; Sen. Murkowski is the ranking member on the Senate Committee on Energy and Natural Resources.

Creating a Linked Data Hub in the Geosciences

NASA Astrophysics Data System (ADS)

Narock, T. W.; Rozell, E. A.; Robinson, E. M.

2012-12-01

Linked data is a paradigm for publishing data on the Web by using, among other things, non-proprietary data formats and resolvable identifiers for things in your dataset. One linked data initiative, DBPedia, is widely used as a "crystallization point" for linked data on the Web. It serves as a hub for links from external datasets covering a broad variety of domains. Within the Earth Science Information Partnership (ESIP) efforts have begun to create a similar crystallization point for linked data in the geosciences. The initial project was created by converting more than 100,000 abstracts from the American Geophysical Union (AGU) into linked data using the Resource Description Framework. Like the Wikipedia data DBPedia is derived from, AGU publications have extremely broad coverage of topics in the geosciences. To better characterize the network, we have linked this AGU data to ESIP meeting and membership data, as well as to National Science Foundation-funded research projects. In doing so, we can visualize connections between different collaborative clusters like the ESIP Community or NSF grantees within the broader Geosciences communities that attend AGU conferences. Efforts to extend this project include - the ability to annotate abstracts, provide links to referenced tools or datasets, and the enabling of a crowd-sourcing approach to co-reference resolution.

Energy and the environment - Application of geosciences to decision-making

USGS Publications Warehouse

Carter, Lorna M.H.

1995-01-01

This volume contains 67 extended abstracts that summarize some of the oral and poster presentations of the tenth annual V. E. McKelvey forum on mineral and energy resources, held in Washington, D.C., Feb. 13-17, 1995. The focus is on our energy resources and the environment, new research techniques, and cooperative efforts between the USGS and industry, State and Federal agencies, universities, and other countries.

Volcanology Curricula Development Aided by Online Educational Resource

NASA Astrophysics Data System (ADS)

Poland, Michael P.; van der Hoeven Kraft, Katrien J.; Teasdale, Rachel

2011-03-01

Using On-Line Volcano Monitoring Data in College and University Courses: The Volcano Exploration Project: Pu`u `Ō`ō (VEPP); Hawaii Volcanoes National Park, Hawaii, 26-30 July 2010; Volcanic activity is an excellent hook for engaging college and university students in geoscience classes. An increasing number of Internet-accessible real-time and near-real time volcano monitoring data are now available and constitute an important resource for geoscience education; however, relatively few data sets are comprehensive, and many lack background information to aid in interpretation. In response to the need for organized, accessible, and well-documented volcano education resources, the U.S. Geological Survey's Hawaiian Volcano Observatory (HVO), in collaboration with NASA and the University of Hawai`i at Manoa, established the Volcanoes Exploration Project: Pu`u `Ō`ō (VEPP). The VEPP Web site (http://vepp.wr.usgs.gov) is an educational resource that provides access, in near real time, to geodetic, seismic, and geologic data from the active Pu`u `Ō`ō eruptive vent on Kilauea volcano, Hawaii, along with background and context information. A strength of the VEPP site is the common theme of the Pu`u `Ō`ō eruption, which allows the site to be revisited multiple times to demonstrate different principles and integrate many aspects of volcanology.

Volcanology curricula development aided by online educational resource

USGS Publications Warehouse

Poland, Michael P.; Van Der Hoeven, Kraft; Teasdale, R.

2011-01-01

Using On-Line Volcano Monitoring Data in College and University Courses: The Volcano Exploration Project: Pu`u `Ō`ō (VEPP); Hawaii Volcanoes National Park, Hawaii, 26–30 July 2010; Volcanic activity is an excellent hook for engaging college and university students in geoscience classes. An increasing number of Internet-accessible real-time and near–real time volcano monitoring data are now available and constitute an important resource for geoscience education; however, relatively few data sets are comprehensive, and many lack background information to aid in interpretation. In response to the need for organized, accessible, and well-documented volcano education resources, the U.S. Geological Survey's Hawaiian Volcano Observatory (HVO), in collaboration with NASA and the University of Hawai`i at Manoa, established the Volcanoes Exploration Project: Pu`u `Ō`ō (VEPP). The VEPP Web site (http://vepp.wr.usgs.gov) is an educational resource that provides access, in near real time, to geodetic, seismic, and geologic data from the active Pu`u `Ō`ō eruptive vent on Kilauea volcano, Hawaii, along with background and context information. A strength of the VEPP site is the common theme of the Pu`u `Ō`ō eruption, which allows the site to be revisited multiple times to demonstrate different principles and integrate many aspects of volcanology.

Geoscience data visualization and analysis using GeoMapApp

NASA Astrophysics Data System (ADS)

Ferrini, Vicki; Carbotte, Suzanne; Ryan, William; Chan, Samantha

2013-04-01

Increased availability of geoscience data resources has resulted in new opportunities for developing visualization and analysis tools that not only promote data integration and synthesis, but also facilitate quantitative cross-disciplinary access to data. Interdisciplinary investigations, in particular, frequently require visualizations and quantitative access to specialized data resources across disciplines, which has historically required specialist knowledge of data formats and software tools. GeoMapApp (www.geomapapp.org) is a free online data visualization and analysis tool that provides direct quantitative access to a wide variety of geoscience data for a broad international interdisciplinary user community. While GeoMapApp provides access to online data resources, it can also be packaged to work offline through the deployment of a small portable hard drive. This mode of operation can be particularly useful during field programs to provide functionality and direct access to data when a network connection is not possible. Hundreds of data sets from a variety of repositories are directly accessible in GeoMapApp, without the need for the user to understand the specifics of file formats or data reduction procedures. Available data include global and regional gridded data, images, as well as tabular and vector datasets. In addition to basic visualization and data discovery functionality, users are provided with simple tools for creating customized maps and visualizations and to quantitatively interrogate data. Specialized data portals with advanced functionality are also provided for power users to further analyze data resources and access underlying component datasets. Users may import and analyze their own geospatial datasets by loading local versions of geospatial data and can access content made available through Web Feature Services (WFS) and Web Map Services (WMS). Once data are loaded in GeoMapApp, a variety options are provided to export data and/or 2D/3D visualizations into common formats including grids, images, text files, spreadsheets, etc. Examples of interdisciplinary investigations that make use of GeoMapApp visualization and analysis functionality will be provided.

Make Change Happen at the Program or Institutional Scale: Converting Community Expertise into Practical Guidance

NASA Astrophysics Data System (ADS)

McDaris, J. R.; Manduca, C. A.; Orr, C. H.

2016-12-01

As geoscience and STEM programs address common challenges like increasing the diversity of graduates or implementing active learning pedagogies, it is important to learn from the experiences of others in the community. Individual faculty members embody a wealth of experience on these topics but distilling that experience into practical guidance that has value for a broad audience is not as simple as knowing exactly what one person did. Context is important, not only because activities used in similar contexts are easier to adapt, but also because activities that work across multiple contexts are more robust. The development of any best practices guidance benefits from the engagement of a community. Synthesizing across multiple viewpoints leads to a consensus that builds on the diversity of individual experiences. The Science Education Resource Center (SERC) at Carleton College has had success generating such resources in geoscience and STEM education. Working with different groups of educators, we have helped develop content around making change happen at the program or institutional levels, increasing the diversity of students graduating in geoscience and STEM, fostering interdisciplinary learning, translating the results of education research into practice, and several others. These resources draw out common practices, situate them in the education research base, and highlight examples of their use in the real world but also communicate the different ways individuals or institutions have adapted these practices for their particular situation. These resources were developed through a group synthesis process involving the contribution of individual or group expertise, a face-to-face meeting of teams working on themes drawn from the contributed work, and asynchronous group revision and review following the meeting. The materials developed via this process provide reliable and adaptable guidance firmly rooted in the community's experience. This presentation will showcase these materials and describe the development process in detail. The materials that have been developed are being added to SERC's For Higher Ed portal (serc.carleton.edu/highered/index.html).

Future of the geoscience profession

DOE Office of Scientific and Technical Information (OSTI.GOV)

Carleton, A.T.

1995-05-01

I want to discuss the future of the energy industry and the geoscience profession. That`s you and me. Is there a future for us? Will there be a need for petroleum? What will we use for energy in the future? Over the past several years, those of us in the energy business have witnessed remarkable changes in our industry and our profession. We must be able to change with the conditions if we are to survive them. To do so, some idea of what the future holds is essential. I will discuss what that future may be and will covermore » these topics: world population and energy demand, exploration and production outlook, environmental considerations, geoscience demographics, education, technology, and government. Much of the statistical data and some of the projections I will discuss have been taken from the report of AAPG`s 21st Century Committee, of which I was a member.« less

On the Cutting Edge: Face-to-Face and Virtual Professional Development for Current and Future Geoscience Faculty

NASA Astrophysics Data System (ADS)

Macdonald, H.; Manduca, C. A.; Mogk, D. W.; Tewksbury, B. J.; Iverson, E. A.; Kirk, K. B.; Beane, R. J.; McConnell, D.; Wiese, K.; Wysession, M. E.

2011-12-01

On the Cutting Edge, a comprehensive, discipline-wide professional development program for current and future geoscience faculty, aims to develop a geoscience professoriate committed to high-quality instruction based on currency in scientific knowledge, good pedagogic practice, and research on learning. Our program provides an integrated workshop series and online teaching resources. Since 2002, we have offered more than 80 face-to-face workshops, virtual workshops and webinars, and hybrid events. Participants come from two-year colleges and four-year colleges and universities. The workshop series is designed to address the needs of faculty in all career stages at the full spectrum of institutions and covering the breadth of the geoscience curriculum. We select timely and compelling topics and create opportunities of interest to faculty. We offer workshops on course design, new geoscience research and pedagogical topics, core geoscience curriculum topics, and introductory courses as well as workshops for early career faculty and for future faculty. Our workshops are designed to model good teaching practice. We set workshop goals that guide workshop planning and evaluation. Workshops are interactive, emphasize participant learning, provide opportunities for participants to interact and share experience/knowledge, provide good resources, give participants time to reflect and to develop action plans, and help transform their ideas about teaching. We emphasize the importance of adaptation in the context of their specific situations. For virtual workshops and webinars we use icebreakers and other structured interactions to build a comfortable workshop community; promote interaction through features on webinar software, chat-aided question and answer, small-group synchronous interactions, and/or discussion boards; plan detailed schedules for workshop events; use asynchronous discussions and recordings of synchronous events given that participants are busy with their daily commitments; and provide sufficient technical support for participants and leaders. The importance of making the workshop useful and immediately applicable does not diminish with virtual events. One key lesson is the need to be purposeful with virtual communication strategies; the discussion boards, chat-aided discussion, and small group interactions need a specific focus, purpose, or product. Both face-to-face and virtual workshops that appear to flow spontaneously reflect extensive planning, a clear understanding of the program and its objectives by everyone involved, and realistic estimates for how long activities will really take. The workshop content and structures that we have developed result in high rates of satisfaction by participants.

Utilizing Geo-Referenced Mobile Game Technology for Universally Accessible Virtual Geology Field Trips

ERIC Educational Resources Information Center

Bursztyn, Natalie; Pederson, Joel; Shelton, Brett; Walker, Andrew; Campbell, Todd

2015-01-01

Declining interest and low persistence is well documented among undergraduate students in Science, Technology, Engineering, and Math in the United States. For geoscience, field trips are important attractors to students, however with high enrollment courses and increasing costs they are becoming rare. We propose in this concept paper that the…

Sustaining a Global Geoscience Workforce-The Case for International Collaboration

NASA Astrophysics Data System (ADS)

Leahy, P. P.; Keane, C. M.

2013-05-01

Maintaining an adequate global supply of qualified geoscientists is a major challenge facing the profession. With global population expected to exceed 9 billion by midcentury, the demand for geoscience expertise is expected to dramatically increase if we are to provide to society the resource base, environmental quality, and resiliency to natural hazards that is required to meet future global demands. The American Geoscience Institute (AGI) has for the past 50 years tracked the supply of geoscientists and their various areas of specialty for the US. However, this is only part of the necessary workforce analysis, the demand side must also be determined. For the past several years, AGI has worked to acquire estimates for workforce demand in the United States. The analysis suggests that by 2021 there will be between 145,000 to 202,000 unfilled jobs in the US. This demand can be partially filled with an increase in graduates (which is occurring at an insufficient pace in the US to meet full demand), increased migration of geoscientists internationally to the US (a challenge since demands are increasing globally), and more career placement of bachelor degree recipients. To understand the global workforce dynamic, it is critical that accurate estimates of global geoscience supply, demand and retirement be available. Although, AGI has focused on the US situation, it has developed international collaborations to acquire workforce data. Among the organizations that have contributed are UNESCO, the International Union of Geological Sciences (IUGS), the Young Earth-Scientists Network, and the Geological Society of Africa. Among the areas of international collaboration, the IUGS Task Group on Global Geoscience Workforce enables the IUGS to take a leadership role in raising the quality of understanding of workforce across the world. During the course of the taskforce's efforts, several key understandings have emerged. First, the general supply of geoscientists is quantifiable with the caveat that the definition of what constitutes a geoscientist does vary from country to country and region to region. Second, the flow of geoscience talent is both complex and dynamic as there are distinct sources and sinks for talent, but as economic conditions and resource demands vary, the migratory paths appear to change rapidly. Finally, the issue of a nationality of a geoscientist is a much more complex concept than it might appear. With the educational centers not always mapping to where demand is, coupled with a truly global geoscience economic enterprise, tracking geoscientists is problematic. As global demand for geoscience continues, measuring the supply and demand globally will become even more critical for geoscientists, their employers, their schools, and their societies to understand to support a healthy profession. However, in the data collection efforts, specific gaps of data are persistent, especially in Latin America where efforts have never been able to be carried beyond initial consultations, and concerns about reported numbers from less open countries expressed by ex-pats regarding what has been reported by those institutions. A truly global and open collaboration is key for the health of the profession in the 21st Century.

Virtualization of the Y.E.S. Congress 2009 Roundtable Symposia (Invited)

NASA Astrophysics Data System (ADS)

Gonzales, L. M.; Gaines, S. M.

2009-12-01

The Y.E.S. Congress 2009 was the first international conference organized by the Y.E.S. Network, an association of early-career geoscientists who represent professional societies, geoscience companies, geoscience departments, and interested policy makers from across the world, in collaboration with the International Year of Planet Earth (IYPE). The conference, hosted by the China University of Geosciences in Beijing, focused on scientific and career challenges faced by early-career geoscientists, with a particular emphasis on how the Y.E.S. Network can work collaboratively and internationally towards solving these challenges and furthering the IYPE motto of “Earth Sciences for Society”. A key features of the Y.E.S. Congress was the implementation of “virtualized” roundtable symposia which engaged senior and early-career geoscientists via presentations, panel discussions, and working group sessions in which strategies related to scientific challenges (i.e. climate change in the polar regions, natural hazards, natural resource sustainability) and academic and career pathway challenges (i.e. academic-industry linkages, gender parity in the geosciences, geoscience education sustainability, and international licensure issues) were developed. These strategies were then tasked to the Y.E.S. Network for further development and implementation. The virtualization of the roundtable symposia facilitated active discussion between those participants and speakers who were physically located at the conference facilities in Beijing with a wider international audience of virtual participants and speakers. This talk will address the key features of the roundtable virtualization, the successes and challenges faced during the pre-conference set-up as well as during the roundtable sessions, and potential future applications.

Developing a geoscience knowledge framework for a national geological survey organisation

NASA Astrophysics Data System (ADS)

Howard, Andrew S.; Hatton, Bill; Reitsma, Femke; Lawrie, Ken I. G.

2009-04-01

Geological survey organisations (GSOs) are established by most nations to provide a geoscience knowledge base for effective decision-making on mitigating the impacts of natural hazards and global change, and on sustainable management of natural resources. The value of the knowledge base as a national asset is continually enhanced by the exchange of knowledge between GSOs as data and information providers and the stakeholder community as knowledge 'users and exploiters'. Geological maps and associated narrative texts typically form the core of national geoscience knowledge bases, but have some inherent limitations as methods of capturing and articulating knowledge. Much knowledge about the three-dimensional (3D) spatial interpretation and its derivation and uncertainty, and the wider contextual value of the knowledge, remains intangible in the minds of the mapping geologist in implicit and tacit form. To realise the value of these knowledge assets, the British Geological Survey (BGS) has established a workflow-based cyber-infrastructure to enhance its knowledge management and exchange capability. Future geoscience surveys in the BGS will contribute to a national, 3D digital knowledge base on UK geology, with the associated implicit and tacit information captured as metadata, qualitative assessments of uncertainty, and documented workflows and best practice. Knowledge-based decision-making at all levels of society requires both the accessibility and reliability of knowledge to be enhanced in the grid-based world. Establishment of collaborative cyber-infrastructures and ontologies for geoscience knowledge management and exchange will ensure that GSOs, as knowledge-based organisations, can make their contribution to this wider goal.

Alliances for Undergraduate Research in the Geosciences Through Collaborative Recruitment

NASA Astrophysics Data System (ADS)

Pandya, R.; Eriksson, S.; Haacker-Santos, R.; Calhoun, A.

2006-12-01

Undergraduate research is a key strategy for encouraging students to pursue graduate school and careers in science end engineering. In the geosciences, where participation by members of underrepresented groups is among the lowest of any science field, these programs must continue and strengthen their efforts to engage students from historically underrepresented groups. A significant limitation on our ability to engage students from historically underrepresented groups comes from the expense, in terms of time and resources, of promoting these career options to talented undergraduates considering a host of STEM careers. Another hurdle is our ability to match students with research projects tailored to their interests. Further complicating this is the challenge of matching students who have culturally motivated geographic constraints—for example, Native students who seek to serve their local community—to relevant opportunities. As a result, we believe that a number of highly qualified students never fully consider careers in the geosciences. To address these obstacles, we propose an alliance of undergraduate research programs in the geosciences. In this model, all members of the alliance would share recruiting, and students would submit a single application forwarded to all alliance members. The Alliance could offer applicants multiple research opportunities, from across the alliance, tailored to fit the applicant's needs and interests. This strategy has proven very effective in other fields; for example, the Leadership Alliance allows 32 member institutions to offer internships and fellowships through one central application process. SOARS and RESESS, programs in atmospheric science and geophysics, respectively, have done this co-recruiting for two years. There are many benefits to this type of alliance. First, it would allow programs to leverage and coordinate their recruiting investments. From our experience with SOARS and RESESS, much of the effort in recruiting involves education about careers in the geosciences. By collaborating to build awareness of the geosciences, all partnering institutions and programs would have access to a larger applicant pool, thus enabling them to select the most qualified applicants for their programs. Second, applicants could be more easily matched with programs fitting their stated research interests. Third, fewer highly qualified applicants would be overlooked and discouraged from approaching a career in geosciences. By focusing alliance activities on attracting students form underrepresented groups who have not considered geoscience careers, we could increase the number of students from underrepresented groups who pursue careers in geoscience fields. Our presentation will describe the initial SOARS/RESESS collaboration, next steps to build the alliance, and invite additional participation in the alliance.

On-line Resources for Teaching Sustainability

NASA Astrophysics Data System (ADS)

Bruckner, M. Z.; Larsen, K.; Buhr, S. M.; Kirk, K. B.; Ledley, T. S.; Manduca, C. A.; Mogk, D. W.; Savina, M. E.; Tewksbury, B. J.

2012-12-01

Sustainability encompasses broad interdisciplinary topics such as climate change, agricultural food production, and water resource use that include both scientific and societal components. Today's students will need to learn how to address complex, interdisciplinary, sustainability-related challenges throughout their lives. To support faculty in teaching complex concepts in sustainability to undergraduates, the Science Education Resource Center (SERC) now provides integrated access to all resources on teaching sustainability developed by projects hosted on SERC websites. Drawing extensively from collections developed by On the Cutting Edge: Professional Development for Geoscience Faculty, InTeGrate: Interdisciplinary Teaching of Geoscience for a Sustainable Future, the Climate Literacy and Energy Awareness Network (CLEAN), as well as more than 10 smaller projects, these resources include browsable access to (1) over 120 course descriptions submitted by faculty that provide information about course goals, assessments, and syllabi used in teaching courses with a sustainability focus, (2) over 160 faculty-submitted descriptions of activities that can be used to incorporate and address sustainability concepts, and (3) more than 90 interdisciplinary essays that highlight how faculty incorporate sustainability concepts into their teaching. The Sustainability Portal additionally includes several collections of lessons focused on a central theme, such as carbon footprint exercises and materials for teaching about energy that incorporate quantitative skills. The Sustainability Portal provides access to information about incorporating sustainability issues into geoscience courses and examples of how these concepts can be taught for topics such as geology and human health, public policy and Earth science, complex systems, urban students and urban environments, energy, and climate change. A rich collection of innovative pedagogical approaches conducive to teaching about sustainability are presented in the portal, including service learning, campus-based learning, experience-based environmental projects, and teaching with an Earth systems approach. Faculty can find more information about how to get involved with sustainability projects through webinars, workshops, web page authoring, and other professional development opportunities via links to projects such as On the Cutting Edge, CLEAN, and InTeGrate. The Sustainability Portal also provides access to materials generated from previous workshops, featuring interdisciplinary visions for teaching sustainability to undergraduate students. The SERC portal for Teaching Sustainability can be found at the URL below.

Environmental Sciences Division annual progress report for period ending September 30, 1990

DOE Office of Scientific and Technical Information (OSTI.GOV)

Not Available

1991-04-01

The Environmental Sciences Division (ESD) of Oak Ridge National Laboratory (ORNL) conducts research on the environmental aspects of existing and emerging energy systems and applies this information to ensure that technology development and energy use are consistent with national environmental health and safety goals. Offering an interdisciplinary resource of staff and facilities to address complex environmental problems, the division is currently providing technical leadership for major environmental issues of national concern: (1) acidic deposition and related environmental effects, (2) effects of increasing concentrations of atmospheric CO{sub 2} and the resulting climatic changes to ecosystems and natural and physical resources, (3)more » hazardous chemical and radioactive waste disposal and remediation research and development, and (4) development of commercial biomass energy production systems. This progress report outlines ESD's accomplishments in these and other areas in FY 1990. Individual reports are processed separately for the data bases in the following areas: ecosystem studies; environmental analyses; environmental toxicology; geosciences; technical and administrative support; biofuels feedstock development program; carbon dioxide information analysis and research program; and environmental waste program.« less

The Challenges for Persistence with Two-Year College Student Transfers and How One Survey Attempts to Identify Pathways of Success for Geoscience Students

NASA Astrophysics Data System (ADS)

Wilson, C. E.; Van Der Hoeven Kraft, K.; Wolfe, B.

2014-12-01

With the rapid growth in enrollments at two-year colleges (2YCs), these institutions provide a rich talent pool for future science, technology, engineering, and math (STEM) graduates at four-year universities, particularly students from underrepresented groups (American Geosciences Institute [AGI], 2014). This is particularly true for the geosciences because over 25% of recent geoscience graduates with a bachelor's degree attended a 2YC for at least one semester (AGI, 2013). However, it is difficult to successfully track 2YC transfers because many 2YC students do not complete an associate's degree and very few institutions offer a geoscience-specific associate's degree. In order to recruit future geoscientists from this pool of students, researchers need to better understand the barriers these students face when trying to transfer and how they are able to successfully navigate these barriers. During spring 2014 graduation, AGI surveyed students completing their bachelor's, master's, and doctoral degrees about their educational background, experiences and future plans after graduation. Those graduates who attended a 2YC for at least one semester provided insight into their enrollment decisions as they transferred into a four-year university. The sample from this survey represents 154 responses from a total of 596 responses. General demographics reveal an older population (average age: 30, median: 27), a higher percent of male students (54% male, 40% female) and Caucasians (76%, 10% non Caucasian) than a traditional 2YC student. Students attending 2YC nationally are on average 28 years old (median: 24), are 57% women, and are 51% Caucasian (AACC Fast Facts, 2014). In addition, responses indicated some of the factors that influenced their ability to successfully transfer into 4-year geoscience programs including personal motivation and successful transfer of credits.

Mind the Gap: furthering the development of EU-US collaboration in marine geoscience.

NASA Astrophysics Data System (ADS)

Glaves, H.; Miller, S.; Schaap, D.

2012-04-01

There is a large and ever increasing amount of marine geological and geophysical data available throughout Europe, the USA and beyond. The challenges associated with the acquisition of this data mean that the cost of collecting it is very high and there is therefore a need to maximise the potential re-use of this data wherever possible. Facilitating this is becoming an increasingly important aspect of marine geosciences data management as the need for marine data increases at a time when the financial resources for data acquisition are being dramatically reduced. A significant barrier to the re-use of marine geoscience data is the variety of different formats, standards, vocabularies etc which have been used by the various organisations engaged with the collection and management of marine geosciences data at a regional, national and international scale. This is also proving to be a barrier to the development of interoperability with other data types at a time when there is a need to develop a more holistic approach to marine research. These challenges are currently being addressed within Europe by a number of EU funded initiatives, the objectives of which are an improvement in the discovery and access to marine data. The Geo-Seas project is just one of these initiatives, the focus of which is the development of an e-infrastructure for the delivery of standardised marine geological and geophysical data across Europe. The project is developing this e-infrastructure by adopting and adapting the methodologies of the SeaDataNet project which currently provides an e-infrastructure for the management of oceanographic data. This re-use of the existing technologies has lead to the development a joint multidisciplinary e-infrastructure for the delivery or both geoscientific and oceanographic data. In order to expand these initiatives further and bridge the gap between these European projects and those being undertaken by colleagues in both the US and elsewhere a number of collaborative relationships have been developed. To further these growing collaborative relationships a new EU initiative has recently been proposed in parallel with the relevant funding agencies in the USA and Australia with the objective of developing common standards and methodologies which will allow the development of a common multidisciplinary approach to marine science on an international scale.

Integrating geoscience and Native American experiences through a multi-state geoscience field trip for high school students

NASA Astrophysics Data System (ADS)

Kelso, P. R.; Brown, L. M.; Spencer, M.; Sabatine, S.; Goetz, E. R.

2012-12-01

Lake Superior State University (LSSU) developed the GRANITE (Geological Reasoning And Natives Investigating The Earth) to engage high school students in the geosciences. The GRANITE program's target audience is Native American high school students and other populations underrepresented in the geosciences. Through the GRANITE program students undertake a variety of field and laboratory geosciences activities that culminates in a two week summer geoscience field experience during which they travel from Michigan to Wyoming. The sites students visit were selected because of their interesting and diverse geologic features and because in many cases they have special significance to Native American communities. Examples of the processes and localities studied by GRANITE students include igneous processes at Bear Butte, SD (Mato Paha) and Devil's Tower, WY (Mato Tipila); sedimentary processes in the Badlands, SD (Mako Sica) and Black Hills, SD (Paha Sapa); karst processes at Wind Cave, SD (Wasun Niye) and Vore Buffalo Jump; structural processes at Van Hise rock, WI and Dillon normal fault Badlands, SD; hydrologic and laucustrine processes along the Great Lakes and at the Fond du Lac Reservation, MN; fluvial processes along the Mississippi and Missouri rivers; geologic resources at the Homestake Mine, SD and Champion Mine, MI; and metamorphic processes at Pipestone, MN and Baraboo, WI. Through the GRANITE experience students develop an understanding of how geoscience is an important part of their lives, their communities and the world around them. The GRANITE program also promotes each student's growth and confidence to attend college and stresses the importance of taking challenging math and science courses in high school. Geoscience career opportunities are discussed at specific geologic localities and through general discussions. GRANITE students learn geosciences concepts and their application to Native communities and society in general through activities and experiences led by Lake Superior State University professors, K-12 earth science teachers, local science experts (most with tribal affiliation), and local Native American leaders. Student selection is based on an application that includes academic background and performance, a personal essay, and teacher and counselor references. All of the students invited to be part of the GRANITE program participated in the summer field excursion. The GRANITE summer field trip was structured to address over 50% of Michigan's high school geology standards. Each student's geoscience knowledge and interest is assessed through questionnaires administered pre- and post the summer field experience. Also, student feedback is gathered during the GRANITE field trip and more than six months post field trip. Students recorded field observations and discussion in their field books which they used to produce powerpoint slides summarizing and reflecting upon what they did and learned each day. Students' post field excursion, content-oriented scores increased each of the three years of the program. In addition to geosciences content growth, all of the students responded affirmatively that GRANITE "increased my understanding of how geoscientists study the Earth "and "increased my knowledge of the importance of geoscience to our society."

Internet-accessible, near-real-time volcano monitoring data for geoscience education: the Volcanoes Exploration Project—Pu`u `O`o

NASA Astrophysics Data System (ADS)

Poland, M. P.; Teasdale, R.; Kraft, K.

2010-12-01

Internet-accessible real- and near-real-time Earth science datasets are an important resource for geoscience education, but relatively few comprehensive datasets are available, and background information to aid interpretation is often lacking. In response to this need, the U.S. Geological Survey’s (USGS) Hawaiian Volcano Observatory, in collaboration with the National Aeronautics and Space Administration and the University of Hawai‘i, Mānoa, established the Volcanoes Exploration Project: Pu‘u ‘O‘o (VEPP). The VEPP Web site provides access, in near-real time, to geodetic, seismic, and geologic data from the Pu‘u ‘O‘o eruptive vent on Kilauea Volcano, Hawai‘i. On the VEPP Web site, a time series query tool provides a means of interacting with continuous geophysical data. In addition, results from episodic kinematic GPS campaigns and lava flow field maps are posted as data are collected, and archived Webcam images from Pu‘u ‘O‘o crater are available as a tool for examining visual changes in volcanic activity over time. A variety of background information on volcano surveillance and the history of the 1983-present Pu‘u ‘O‘o-Kupaianaha eruption puts the available monitoring data in context. The primary goal of the VEPP Web site is to take advantage of high visibility monitoring data that are seldom suitably well-organized to constitute an established educational resource. In doing so, the VEPP project provides a geoscience education resource that demonstrates the dynamic nature of volcanoes and promotes excitement about the process of scientific discovery through hands-on learning. To support use of the VEPP Web site, a week-long workshop was held at Kilauea Volcano in July 2010, which included 25 participants from the United States and Canada. The participants represented a diverse cross-section of higher learning, from community colleges to research universities, and included faculty who teach both large introductory non-major classes and seminar-style upper division and graduate-level classes. Overall workshop goals were for participants to learn how to interpret each of the VEPP data types, become proficient in the use of the VEPP Web site, provide feedback on site content, and create teaching modules that integrate the site into college and university geoscience curriculum. By the end of the workshop, over 20 new teaching modules were developed and the VEPP Web site was modified based on participant feedback. Teaching activities are available via the VEPP Workshop section of the Science Education Resource Center (SERC) Web site (http://www.nagt.org/nagt/vepp/index.html).

NAGT: Partnering to Expand and Improve the Teaching of Earth Sciences at all Levels of Instruction while Increasing Earth Literacy to the General Public

NASA Astrophysics Data System (ADS)

Herbstrith, K. G.

2016-12-01

Now more than ever, we need an Earth literate public and a workforce that can develop and be engaged in viable solutions to current and future environmental and resource challenges. The National Association of Geoscience Teachers (NAGT) is a member driven organization dedicated to fostering improvement in the teaching of the Earth Sciences at all levels of formal and informal instruction, to emphasizing the cultural significance of the Earth sciences and to disseminating knowledge in this field to the general public. NAGT offers a number of ways to partner and collaborate including our sponsored sessions, events and programs; two publications; workshop programming; three topical focused divisions; educational advocacy; and website offerings hosted through the Science Education Resource Center (SERC). A growing number of associations, institutions, projects, and individual educators are strengthening their professional networks by partnering with NAGT. Locating and connecting members of the Earth education community with shared values and interest is an important part of collaborating and NAGT's topical divisions assist community members who wish to work on the topics of 2-year college faculty, geoscience education research, and teacher preparation. The NAGT website and the linked websites of its collaborating partners provides a peer reviewed venue for educators to showcase their pedagogy and to learn best practices of others. The annual Earth Educators' Rendezvous is an opportunity to network face-to-face with the Earth education community, strengthening our relationships while working with those who share our interests and challenges while also learning from those who have divergent experiences. NAGT is a non-profit organization that advocates for the advancement of the geosciences and supports the work of Earth educators and geoscience education researchers. For more information about NAGT, visit our website at www.nagt.org

A Compilation and Review of over 500 Geoscience Misconceptions

NASA Astrophysics Data System (ADS)

Francek, Mark

2013-01-01

This paper organizes and analyses over 500 geoscience misconceptions relating to earthquakes, earth structure, geologic resources, glaciers, historical geology, karst (limestone terrains), plate tectonics, rivers, rocks and minerals, soils, volcanoes, and weathering and erosion. Journal and reliable web resources were reviewed to discover (1) the frequency of misconceptions by subject matter, group (primary, middle-school, high-school, middle-/high-school, college, pre-service teachers, in-service teachers, and undefined) and source (journal versus web); and (2) the pattern of misconceptions across age groups and (3) directions for future research. A total of 502 misconceptions were discovered, with over 40% targeting a middle- and high-school audience. Plate tectonics comprised 19% of all misconceptions, with another 14% and 13% associated with weathering/erosion and historical geology, respectively. Over 80% of all the misconceptions were derived from peer-reviewed journals or web sources, the rest originated from reliable sources on the World Wide Web. The supernatural origin for many of the geoscience phenomena listed here is abandoned by middle school, but in other cases, some misconceptions seem robust through adulthood. Examples of such misconceptions include the origin/pattern of earthquakes, thickness of the earth's crust, oil's origin, movement mechanisms for glaciers, co-existence of humans and dinosaurs, water movement within karst terrains, the nature of plate boundaries, the power of water as an agent of geomorphic change, what constitutes a mineral and a rock, thickness of the soil layer, the distribution of volcanoes, and the difference between weathering and erosion.

Connecting long-tail scientists with big data centers using SaaS

NASA Astrophysics Data System (ADS)

Percivall, G. S.; Bermudez, L. E.

2012-12-01

Big data centers and long tail scientists represent two extremes in the geoscience research community. Interoperability and inter-use based on software-as-a-service (SaaS) increases access to big data holdings by this underserved community of scientists. Large, institutional data centers have long been recognized as vital resources in the geoscience community. Permanent data archiving and dissemination centers provide "access to the data and (are) a critical source of people who have experience in the use of the data and can provide advice and counsel for new applications." [NRC] The "long-tail of science" is the geoscience researchers that work separate from institutional data centers [Heidorn]. Long-tail scientists need to be efficient consumers of data from large, institutional data centers. Discussions in NSF EarthCube capture the challenges: "Like the vast majority of NSF-funded researchers, Alice (a long-tail scientist) works with limited resources. In the absence of suitable expertise and infrastructure, the apparently simple task that she assigns to her graduate student becomes an information discovery and management nightmare. Downloading and transforming datasets takes weeks." [Foster, et.al.] The long-tail metaphor points to methods to bridge the gap, i.e., the Web. A decade ago, OGC began building a geospatial information space using open, web standards for geoprocessing [ORM]. Recently, [Foster, et.al.] accurately observed that "by adopting, adapting, and applying semantic web and SaaS technologies, we can make the use of geoscience data as easy and convenient as consumption of online media." SaaS places web services into Cloud Computing. SaaS for geospatial is emerging rapidly building on the first-generation geospatial web, e.g., OGC Web Coverage Service [WCS] and the Data Access Protocol [DAP]. Several recent examples show progress in applying SaaS to geosciences: - NASA's Earth Data Coherent Web has a goal to improve science user experience using Web Services (e.g. W*S, SOAP, RESTful) to reduce barriers to using EOSDIS data [ECW]. - NASA's LANCE provides direct access to vast amounts of satellite data using the OGC Web Map Tile Service (WMTS). - NOAA's Unified Access Framework for Gridded Data (UAF Grid) is a web service based capability for direct access to a variety of datasets using netCDF, OPeNDAP, THREDDS, WMS and WCS. [UAF] Tools to access SaaS's are many and varied: some proprietary, others open source; some run in browsers, others are stand-alone applications. What's required is interoperability using web interfaces offered by the data centers. NOAA's UAF service stack supports Matlab, ArcGIS, Ferret, GrADS, Google Earth, IDV, LAS. Any SaaS that offers OGC Web Services (WMS, WFS, WCS) can be accessed by scores of clients [OGC]. While there has been much progress in the recent year toward offering web services for the long-tail of scientists, more needs to be done. Web services offer data access but more than access is needed for inter-use of data, e.g. defining data schemas that allow for data fusion, addressing coordinate systems, spatial geometry, and semantics for observations. Connecting long-tail scientists with large, data centers using SaaS and, in the future, semantic web, will address this large and currently underserved user community.

Geoscience Information Network (USGIN) Solutions for Interoperable Open Data Access Requirements

NASA Astrophysics Data System (ADS)

Allison, M. L.; Richard, S. M.; Patten, K.

2014-12-01

The geosciences are leading development of free, interoperable open access to data. US Geoscience Information Network (USGIN) is a freely available data integration framework, jointly developed by the USGS and the Association of American State Geologists (AASG), in compliance with international standards and protocols to provide easy discovery, access, and interoperability for geoscience data. USGIN standards include the geologic exchange language 'GeoSciML' (v 3.2 which enables instant interoperability of geologic formation data) which is also the base standard used by the 117-nation OneGeology consortium. The USGIN deployment of NGDS serves as a continent-scale operational demonstration of the expanded OneGeology vision to provide access to all geoscience data worldwide. USGIN is developed to accommodate a variety of applications; for example, the International Renewable Energy Agency streams data live to the Global Atlas of Renewable Energy. Alternatively, users without robust data sharing systems can download and implement a free software packet, "GINstack" to easily deploy web services for exposing data online for discovery and access. The White House Open Data Access Initiative requires all federally funded research projects and federal agencies to make their data publicly accessible in an open source, interoperable format, with metadata. USGIN currently incorporates all aspects of the Initiative as it emphasizes interoperability. The system is successfully deployed as the National Geothermal Data System (NGDS), officially launched at the White House Energy Datapalooza in May, 2014. The USGIN Foundation has been established to ensure this technology continues to be accessible and available.

A Potential Synergy Connecting Educational Leadership, The Geoscience Community, and Spatial Data

NASA Astrophysics Data System (ADS)

Branch, B. D.

2008-12-01

The effort to promote more geosciences numbers and greater diversity should reference considerations of federal policy. In congruence, institutions need to include geosciences education in the K-12 curriculum in order to increase the numbers of geoscientists and to increase diversity among geoscientists. For example, No Child Left Behind stated public entities should, ""(1) to carry out programs that prepare prospective teachers to use advanced technology to prepare all students to meet challenging", section 1051 sub section 221. Moreover, Executive Order 12906, the Spatial Data Infrastructure Act, requires all federal agencies to manage their spatial data. Such compliance may influence the job market, education and policy makers to see that spatial thinking transcends the standard course of study. Namely, educational leadership and policy have to be a vital aid to augment the geosciences experience through the K-12 experience and as an inclusion activity in the standard course of study agenda. A simple endorsement by the National Academy of Sciences (2006), in their work titled Learning to think spatially: GIS as a support system in the K-12 curriculum, who stated, "Spatial thinking can be learned, and it can and should be taught at all levels in the education system" (p.3). Such may not be enough to gain the attention and time consideration of educational leadership. Therefore, the challenge for progressive advocates of geosciences is that some may have to consider educational leadership as new frontier to push such policy and research issues.

Transduction between worlds: using virtual and mixed reality for earth and planetary science

NASA Astrophysics Data System (ADS)

Hedley, N.; Lochhead, I.; Aagesen, S.; Lonergan, C. D.; Benoy, N.

2017-12-01

Virtual reality (VR) and augmented reality (AR) have the potential to transform the way we visualize multidimensional geospatial datasets in support of geoscience research, exploration and analysis. The beauty of virtual environments is that they can be built at any scale, users can view them at many levels of abstraction, move through them in unconventional ways, and experience spatial phenomena as if they had superpowers. Similarly, augmented reality allows you to bring the power of virtual 3D data visualizations into everyday spaces. Spliced together, these interface technologies hold incredible potential to support 21st-century geoscience. In my ongoing research, my team and I have made significant advances to connect data and virtual simulations with real geographic spaces, using virtual environments, geospatial augmented reality and mixed reality. These research efforts have yielded new capabilities to connect users with spatial data and phenomena. These innovations include: geospatial x-ray vision; flexible mixed reality; augmented 3D GIS; situated augmented reality 3D simulations of tsunamis and other phenomena interacting with real geomorphology; augmented visual analytics; and immersive GIS. These new modalities redefine the ways in which we can connect digital spaces of spatial analysis, simulation and geovisualization, with geographic spaces of data collection, fieldwork, interpretation and communication. In a way, we are talking about transduction between real and virtual worlds. Taking a mixed reality approach to this, we can link real and virtual worlds. This paper presents a selection of our 3D geovisual interface projects in terrestrial, coastal, underwater and other environments. Using rigorous applied geoscience data, analyses and simulations, our research aims to transform the novelty of virtual and augmented reality interface technologies into game-changing mixed reality geoscience.

Grand Canyon as a universally accessible virtual field trip for intro Geoscience classes using geo-referenced mobile game technology

NASA Astrophysics Data System (ADS)

Bursztyn, N.; Pederson, J. L.; Shelton, B.

2012-12-01

There is a well-documented and nationally reported trend of declining interest, poor preparedness, and lack of diversity within U.S. students pursuing geoscience and other STEM disciplines. We suggest that a primary contributing factor to this problem is that introductory geoscience courses simply fail to inspire (i.e. they are boring). Our experience leads us to believe that the hands-on, contextualized learning of field excursions are often the most impactful component of lower division geoscience classes. However, field trips are becoming increasingly more difficult to run due to logistics and liability, high-enrollments, decreasing financial and administrative support, and exclusivity of the physically disabled. Recent research suggests that virtual field trips can be used to simulate this contextualized physical learning through the use of mobile devices - technology that exists in most students' hands already. Our overarching goal is to enhance interest in introductory geoscience courses by providing the kinetic and physical learning experience of field trips through geo-referenced educational mobile games and test the hypothesis that these experiences can be effectively simulated through virtual field trips. We are doing this by developing "serious" games for mobile devices that deliver introductory geology material in a fun and interactive manner. Our new teaching strategy will enhance undergraduate student learning in the geosciences, be accessible to students of diverse backgrounds and physical abilities, and be easily incorporated into higher education programs and curricula at institutions globally. Our prototype involves students virtually navigating downstream along a scaled down Colorado River through Grand Canyon - physically moving around their campus quad, football field or other real location, using their smart phone or a tablet. As students reach the next designated location, a photo or video in Grand Canyon appears along with a geological question. The students must answer each question correctly in order to proceed to the next location and accrue points in the game and multiple attempts reduce the number of points earned when the correct answer is found. The questions are either multiple choice or involve touch-screen interaction to identify a specific geologic feature. Initial testing of the prototype game in Historical and Physical geology courses at Utah State University indicate that students enjoy the mobile "exploration" nature of the game as well as experiencing photographs of geologic features rather than traditional cartoons. Qualitative evaluation using anonymous surveys was conducted to help determine the usability of the game and the potential effectiveness of this technology-based approach. Students were asked about the degree of fun and difficulty of the game, content learned, and their overall response to features they liked/disliked about it. The results of these early assessments are positive, both in regard to the improvement of students' understanding of key geology concepts and their enjoyment of learning with the technology in a mobile orienteering manner. This is a positive first step in an innovative teaching tool with the power to overcome the pervasive problem of the boring first year STEM course and make world-class field trips accessible to all.

A Google Earth Grand Tour of the Terrestrial Planets

ERIC Educational Resources Information Center

De Paor, Declan; Coba, Filis; Burgin, Stephen

2016-01-01

Google Earth is a powerful instructional resource for geoscience education. We have extended the virtual globe to include all terrestrial planets. Downloadable Keyhole Markup Language (KML) files (Google Earth's scripting language) associated with this paper include lessons about Mercury, Venus, the Moon, and Mars. We created "grand…

INSPIRE: Initiating New Science Partnerships in Rural Education

NASA Astrophysics Data System (ADS)

Pierce, Donna M.; McNeal, K. S.; Bruce, L. M.; Harpole, S. H.; Schmitz, D. W.

2010-10-01

INSPIRE, Initiating New Science Partnerships in Rural Education, is a partnership between Mississippi State University and three school districts in Mississippi's Golden Triangle (Starkville, Columbus, West Point). This program recruits ten graduate fellows each year from geosciences, physics, astronomy, and engineering and pairs them with a participating middle school or high school teacher. The graduate fellows provide technology-supported inquiry-based learning in the earth and space sciences by incorporating their research into classroom instruction and using multiple resources such as Google Earth, geographic information systems (GIS), Celestia, and others. In addition to strengthening the communication skills of the graduate fellows, INSPIRE will increase the content knowledge of participating teachers, provide high-quality instruction using multiple technologies, promote higher education to area high-school students, and provide fellows and teachers with international research experience through our partners in Australia, The Bahamas, England, and Poland. INSPIRE is funded by the Graduate STEM Fellows in K-12 Education Program (GK-12; Award No. DGE-0947419), which is part of the Division for Graduate Education of the National Science Foundation.

The Y.E.S. Network: An IYPE legacy for engaging future generations of early-career geoscientists

NASA Astrophysics Data System (ADS)

Gonzales, L. M.; Govoni, D.; Micucci, L.; Gaines, S. M.; Venus, J.; Meng, W.

2009-12-01

The Y.E.S. Network, an association of early-career geoscientists who represent professional societies, geoscience companies, and geoscience departments from across the world, was formed as a direct result of the International Year of Planet Earth (IYPE). Currently the Y.E.S. Network has representatives in thirty-five countries from six continents. The goal of the network is to engage early-career representatives from geological associations and institutions, policy-makers, and delegates from administrative bodies to establish a worldwide network of future leaders, policy-makers and geoscientists who will work collaboratively to address the scientific challenges future generations will face. To this end, the Y.E.S. Network, in collaboration with IYPE and with the patronage of UNESCO, organized the first international Y.E.S. Congress which was hosted by the China University of Geosciences in Beijing. The conference focused on scientific and career challenges faced by early-career geoscientists, with a particular emphasis on how the Y.E.S. Network can work collaborative and internationally towards solving these challenges and furthering the IYPE motto of “Earth Sciences for Society”. The conference focused on the ten major themes of the IYPE (e.g. health, climate, groundwater, ocean, soils, deep earth, megacities, hazards, resources, and life) at its poster and oral sessions. Roundtable symposia engaged senior and early-career geoscientists via presentations, panel discussions, and working group sessions where strategies related to scientific challenges (i.e. climate change in the polar regions, natural hazards, natural resource sustainability) and academic and career pathway challenges (i.e. academic-industry linkages, gender parity in the geosciences, geoscience education sustainability, and international licensure issues) were developed. These strategies were then tasked to the Y.E.S. Network for further development and implementation. Future Y.E.S. Network activities include the development of an interactive Y.E.S. Network website that will enable Y.E.S. country representative to post relevant events and activities, and will facilitate continued collaboration between Y.E.S. Network members on the strategies developed at the Y.E.S. Congress roundtable symposia. The next international Y.E.S. Congress will be held in conjunction with the 34th IGC in Brisbane, Australia in August 2012.

PLUS: 'Planning Land Use with Students' is a Local Land Use Policy That Showcase the Geosciences

NASA Astrophysics Data System (ADS)

Turrin, M.

2014-12-01

Land Use decisions in the local community are well represented in geoscience topics and issues, and provide an excellent opportunity to showcase a wide range of geoscience careers to high school students. In PLUS (Planning Land Use with Students) we work with youth corps, volunteer agencies and the County Departments of Planning, Transportation, Public Health, Water Resources to run a program for high school seniors to engage the students in the complex layers of decision making connected with land use as we showcase geoscience careers (http://www.ldeo.columbia.edu/edu/plus/index.html). How development occurs, what resources are in use and who makes these decisions is both interesting and relevant for students. We develop case studies around current, active, local land use issues large enough in scale to have a formal environmental review at the County and/or the State level. Sections of each case study are dedicated to addressing the range of environmental issues that are central to each land use decision. Water, its availability, planned use and treatment on the site, brings in both a review of local hydrology and a discussion of storm water management. Air quality and the impact of the proposed project's density, transportation plans, and commercial and industrial uses brings in air quality issues like air quality ratings, existing pollution, and local air monitoring. A review of the site plans brings in grading plans for the project area, which highlights issues of drainage, soil stability, and exposure to toxins or pollutants depending on the historic use of the site. Brownfield redevelopments are especially challenging with various monitoring, clean up and usage restrictions that are extremely interesting to the students. Students' work with mentors from the community who represent various roles in the planning process including a range of geosciences, community business members and other players in the planning process. This interplay of individuals provides a realistic look at the forces that move land use decision-making in a community. Discussion of impacts and mitigations highlight the intersection of policy and science. Debate arises on how much science should guide policy and how much land use policy decisions require science monitoring, pushing new scientific developments.

Climate Discovery Online Courses for Educators from NCAR

NASA Astrophysics Data System (ADS)

Henderson, S.; Ward, D. L.; Meymaris, K. K.; Johnson, R. M.; Gardiner, L.; Russell, R.

2008-12-01

The National Center for Atmospheric Research (NCAR) has responded to the pressing need for professional development in climate and global change sciences by creating the Climate Discovery online course series. This series was designed with the secondary geoscience educator in mind. The online courses are based on current and credible climate change science. Interactive learning techniques are built into the online course designs with assignments that encourage active participation. A key element of the online courses is the creation of a virtual community of geoscience educators who exchange ideas related to classroom implementation, student assessment, and lessons plans. Geoscience educators from around the country have participated in the online courses. The ongoing interest from geoscience educators strongly suggests that the NCAR Climate Discovery online courses are a timely and needed professional development opportunity. The intent of NCAR Climate Discovery is to positively impact teachers' professional development scientifically authentic information, (2) experiencing guided practice in conducting activities and using ancillary resources in workshop venues, (3) gaining access to standards-aligned lesson plans, kits that promote hands-on learning, and scientific content that are easily implemented in their classrooms, and (4) becoming a part of a community of educators with whom they may continue to discuss the challenges of pedagogy and content comprehension in teaching climate change in the Earth system context. Three courses make up the Climate Discovery series: Introduction to Climate Change; Earth System Science - A Climate Change Perspective; and Understanding Climate Change Today. Each course, instructed by science education specialists, combines geoscience content, information about current climate research, hands-on activities, and group discussion. The online courses use the web-based Moodle courseware system (open- source software similar to Blackboard and webCT), utilizing its features to promote dialogue as well as provide rich online content and media. A key element of the online courses is the development and support of an online learning community, an essential component in successful online courses. Interactive learning techniques are built into the course designs with assignments that encourage active participation. Educators (both formal and informal) use the courses as a venue to exchange ideas and teaching resources. A unique feature of the courses is the emphasis on hands-on activities, a hallmark of our professional development efforts. This presentation will focus on the lessons learned in the development of the three online courses and our successful recruitment and retention efforts.

Resourcing Future Generations - Challenges for geoscience: a new IUGS initiative

NASA Astrophysics Data System (ADS)

Oberhänsli, Roland; Lambert, Ian

2014-05-01

In a world with rapidly increasing population and technological development new space based remote sensing tools allowed for new discoveries and production of water, energy- and mineral-resources, including minerals, soils and construction materials. This has impact on politics, socio-economic development and thus calls for a strong involvement of geosciences because one of humanities biggest challenges will be, to rise living standards particularly in less developed countries. Any growth will lead to an increase of demand for natural resources. But especially for readily available mineral resources supply appears to be limited. Particularly demand for so called high-tech commodities - platinum group or rare earth elements - increased. This happened often faster than new discoveries were made. All this, while areas available for exploration decreased as the need for urban and agricultural use increased. Despite strong efforts in increasing efficiency of recycling, shortage in some commodities has to be expected. A major concern is that resources are not distributed evenly on our planet. Thus supplies depend on political stability, socio-economic standards and pricing. In the light of these statements IUGS is scoping a new initiative, Resourcing Future Generations (RFG), which is predicated on the fact that mining will continue to be an essential activity to meet the needs of future generations. RFG is aimed at identifying and addressing key challenges involved in securing natural resources to meet global needs post-2030. We consider that mineral resources should be the initial focus, but energy, soils, water resources and land use should also be covered. Addressing the multi-generational needs for mineral and other natural resources requires data, research and actions under four general themes: 1. Comprehensive evaluation and quantification of 21st century supply and demand. 2. Enhanced understanding of subsurface as it relates to mineral (energy and groundwater) resources. 3. Evaluation of where additional natural resources are likely to be found. 4. Building additional capacity and other actions to facilitate delineation and responsible development of natural resources in less developed nations. Of these, Themes 1 and 4 have been judged the most important for RFG. A goal of RFG is to be accepted as an independent, international 'honest broker', which can improve the ability of developing nations to create socioeconomically responsible world-class and regionally self-sufficient mining industries, circumventing potential concerns about the roles of some individual countries and organisations. This would be facilitated by IUGS' good links with UNESCO. A high proportion of the mineral resources that will need to be mined in the future are in underexplored, less developed regions. Responsible production of natural resources needs to be accepted as a pathway to regional/national development. Holistic regional planning required for responsible mining in less developed regions has been commonly hampered by a general lack of infrastructure, governance, geological knowledge and trained workforce necessary to efforts that can responsibly and equitably supply future generations. There is a need to move beyond the paradigm of development aid, which has clearly not worked over the past 50 years, to partnerships based on specific needs. And ethical behaviour is required on all sides

Linking earth science informatics resources into uninterrupted digital value chains

NASA Astrophysics Data System (ADS)

Woodcock, Robert; Angreani, Rini; Cox, Simon; Fraser, Ryan; Golodoniuc, Pavel; Klump, Jens; Rankine, Terry; Robertson, Jess; Vote, Josh

2015-04-01

The CSIRO Mineral Resources Flagship was established to tackle medium- to long-term challenges facing the Australian mineral industry across the value chain from exploration and mining through mineral processing within the framework of an economically, environmentally and socially sustainable minerals industry. This broad portfolio demands collaboration and data exchange with a broad range of participants and data providers across government, research and industry. It is an ideal environment to link geoscience informatics platforms to application across the resource extraction industry and to unlock the value of data integration between traditionally discrete parts of the minerals digital value chain. Despite the potential benefits, data integration remains an elusive goal within research and industry. Many projects use only a subset of available data types in an integrated manner, often maintaining the traditional discipline-based data 'silos'. Integrating data across the entire minerals digital value chain is an expensive proposition involving multiple disciplines and, significantly, multiple data sources both internal and external to any single organisation. Differing vocabularies and data formats, along with access regimes to appropriate analysis software and equipment all hamper the sharing and exchange of information. AuScope has addressed the challenge of data exchange across organisations nationally, and established a national geosciences information infrastructure using open standards-based web services. Federated across a wide variety of organisations, the resulting infrastructure contains a wide variety of live and updated data types. The community data standards and infrastructure platforms that underpin AuScope provide important new datasets and multi-agency links independent of software and hardware differences. AuScope has thus created an infrastructure, a platform of technologies and the opportunity for new ways of working with and integrating disparate data at much lower cost. An early example of this approach is the value generated by combining geological and metallurgical data sets as part of the rapidly growing field of geometallurgy. This not only provides a far better understanding of the impact of geological variability on ore processing but also leads to new thinking on the types and characteristics of data sets collected at various stages of the exploration and mining process. The Minerals Resources Flagship is linking its research activities to the AuScope infrastructure, exploiting the technology internally to create a platform for integrated research across the minerals value chain and improved interaction with industry. Referred to as the 'Early Access Virtual Lab', the system will be fully interoperable with AuScope and international infrastructures using open standards like GeosciML. Secured access is provided to allow confidential collaboration with industry when required. This presentation will discuss how the CSIRO Mineral Resources Flagship is building on the AuScope infrastructure to transform the way that data and data products are identified, shared, integrated, and reused, to unlock the benefits of true integration of research efforts across the minerals digital value chain.

Enabling High-performance Interactive Geoscience Data Analysis Through Data Placement and Movement Optimization

NASA Astrophysics Data System (ADS)

Zhu, F.; Yu, H.; Rilee, M. L.; Kuo, K. S.; Yu, L.; Pan, Y.; Jiang, H.

2017-12-01

Since the establishment of data archive centers and the standardization of file formats, scientists are required to search metadata catalogs for data needed and download the data files to their local machines to carry out data analysis. This approach has facilitated data discovery and access for decades, but it inevitably leads to data transfer from data archive centers to scientists' computers through low-bandwidth Internet connections. Data transfer becomes a major performance bottleneck in such an approach. Combined with generally constrained local compute/storage resources, they limit the extent of scientists' studies and deprive them of timely outcomes. Thus, this conventional approach is not scalable with respect to both the volume and variety of geoscience data. A much more viable solution is to couple analysis and storage systems to minimize data transfer. In our study, we compare loosely coupled approaches (exemplified by Spark and Hadoop) and tightly coupled approaches (exemplified by parallel distributed database management systems, e.g., SciDB). In particular, we investigate the optimization of data placement and movement to effectively tackle the variety challenge, and boost the popularization of parallelization to address the volume challenge. Our goal is to enable high-performance interactive analysis for a good portion of geoscience data analysis exercise. We show that tightly coupled approaches can concentrate data traffic between local storage systems and compute units, and thereby optimizing bandwidth utilization to achieve a better throughput. Based on our observations, we develop a geoscience data analysis system that tightly couples analysis engines with storages, which has direct access to the detailed map of data partition locations. Through an innovation data partitioning and distribution scheme, our system has demonstrated scalable and interactive performance in real-world geoscience data analysis applications.

Characterizing Strong Geoscience Departments: Results of a National Survey

NASA Astrophysics Data System (ADS)

Richardson, R. M.

2005-12-01

In a follow up to a survey of geoscience departments drawn primarily from American Association of Universities (AAU) institutions, we have expanded the number and type of departments to include a much broader range of institutions and to address key issues about factors that department heads and chairs feel are indicative of strong departments. The previous survey, completed at a very high rate of return, indicated that the biggest opportunities at AAU institutions included large, community-wide initiatives, while the biggest threats included declining resources and associated issues such as faculty retention. The new survey follows on a workshop, Building Strong Geoscience Departments, held in February 2005 at which 25 participants discussed the state of geoscience departments and developed ideas for strengthening departments. The new survey addresses departmental demographics of a much broader range of departments and institutions, including two year, primarily undergraduate, and graduate degree-granting departments/institutions. In addition to perceived threats and opportunities, the survey includes aspects and characteristics of strong departments. For example, department heads and chairs respond to a variety of possible attributes of strong departments, including: 1) Defining the mission of the department in such a way that it is aligned with the institutional vision; 2) Taking a proactive stance in building modern and dynamic geoscience curricula and, as appropriate, research agendas; 3) Working effectively as a department team; 4) Acknowledging that recruitment, development, and retention of students, faculty, and staff are key elements of departmental success and working effectively in these areas; 5) Developing strong departmental leaders now and for the future; 6) Communicating success, using effective metrics, to colleagues, senior administrators, students, donors, and friends; and 7) Forging strategic partnerships within the university (e.g., with biosciences, engineering, environmental studies, or geography) and outside the university (e.g., employers or alumni).

Virtual Reality as a Story Telling Platform for Geoscience Communication

NASA Astrophysics Data System (ADS)

Lazar, K.; Moysey, S. M.

2017-12-01

Capturing the attention of students and the public is a critical step for increasing societal interest and literacy in earth science issues. Virtual reality (VR) provides a means for geoscience engagement that is well suited to place-based learning through exciting and immersive experiences. One approach is to create fully-immersive virtual gaming environments where players interact with physical objects, such as rock samples and outcrops, to pursue geoscience learning goals. Developing an experience like this, however, can require substantial programming expertise and resources. At the other end of the development spectrum, it is possible for anyone to create immersive virtual experiences with 360-degree imagery, which can be made interactive using easy to use VR editing software to embed videos, audio, images, and other content within the 360-degree image. Accessible editing tools like these make the creation of VR experiences something that anyone can tackle. Using the VR editor ThingLink and imagery from Google Maps, for example, we were able to create an interactive tour of the Grand Canyon, complete with embedded assessments, in a matter of hours. The true power of such platforms, however, comes from the potential to engage students as content authors to create and share stories of place that explore geoscience issues from their personal perspective. For example, we have used combinations of 360-degree images with interactive mapping and web platforms to enable students with no programming experience to create complex web apps as highly engaging story telling platforms. We highlight here examples of how we have implemented such story telling approaches with students to assess learning in courses, to share geoscience research outcomes, and to communicate issues of societal importance.

Exploring deliberate mentoring approaches aimed at improving the recruitment and persistence of undergraduate women in the geosciences

NASA Astrophysics Data System (ADS)

Pollack, I. B.; Adams, A. S.; Barnes, R.; Bloodhart, B.; Bowker, C.; Burt, M. A.; Clinton, S. M.; Godfrey, E.; Henderson, H.; Hernandez, P. R.; Sample McMeeking, L. B.; Sayers, J.; Fischer, E. V.

2016-12-01

In fall 2015, an interdisciplinary team with expertise in the geosciences, psychology, education, and STEM persistence began a five-year longitudinal project focused on understanding whether a multi-part mentoring program can increase the persistence of undergraduate women in the geosciences. The program focuses on mentoring 1st and 2nd year female undergraduate students from five universities in Colorado and Wyoming and four universities in North and South Carolina, and includes a weekend workshop, mentoring by professional women across geoscience fields, and both in-person and virtual peer networks. In fall 2015, we recruited 85 students from both regions into cohort 1 as well as a propensity score matched group of 255 female students that did not participate in the program. An equal or greater number of students are anticipated for cohort 2 from recruitment in fall 2016. Both cohorts will have attended weekend-long workshops (cohort 1 in October 2015, and cohort 2 in October 2016), which aimed to introduce students to various careers and lifestyles of those working in the geosciences, guide students through their strengths and interests, and address gender biases that students may face. Early analyses indicate that students who are interested in participating in the program are more likely to reject stereotypes and beliefs that the sciences are masculine, and to see science as being compatible with benefitting society. The web-platform (http://geosciencewomen.org/), designed to enable peer-mentoring and provide resources, was launched in fall 2015 and is used by both cohorts. We will present an overview of the major components of the program, early findings from focus group and survey-based feedback from participants, and discuss lessons learned during 2015 that were applied to 2016.

Assessment of undiscovered oil and gas resources of the Anadarko Basin Province of Oklahoma, Kansas, Texas, and Colorado, 2010

USGS Publications Warehouse

Higley, D.K.; Gaswirth, S.B.; Abbott, M.M.; Charpentier, R.R.; Cook, T.A.; Ellis, G.S.; Gianoutsos, N.J.; Hatch, J.R.; Klett, T.R.; Nelson, Philip H.; Pawlewicz, M.J.; Pearson, O.N.; Pollastro, R.M.; Schenk, C.J.

2011-01-01

The U.S. Geological Survey, using a geoscience-based assessment methodology, estimated mean technically-recoverable undiscovered continuous and conventional resources that total 495 million barrels of oil, 27.5 trillion cubic feet of natural gas, and 410 million barrels of natural gas liquids in the Anadarko Basin Province; this assessment includes the Las Animas arch area of southeastern Colorado. The province is at a mature stage of exploration and development for conventional resources. Mean undiscovered continuous resources are estimated at 79 percent of oil, 90 percent of natural gas, and 81 percent of natural gas liquids in the province.

In-Flight Thermal Performance of the Geoscience Laser Altimeter System (GLAS) Instrument

NASA Technical Reports Server (NTRS)

Grob, Eric; Baker, Charles; McCarthy, Tom

2003-01-01

The Geoscience Laser Altimeter System (GLAS) instrument is NASA Goddard Space Flight Center's first application of Loop Heat Pipe technology that provides selectable/stable temperature levels for the lasers and other electronics over a widely varying mission environment. GLAS was successfully launched as the sole science instrument aboard the Ice, Clouds, and Land Elevation Satellite (ICESat) from Vandenberg AFB at 4:45pm PST on January 12, 2003. After SC commissioning, the LHPs started easily and have provided selectable and stable temperatures for the lasers and other electronics. This paper discusses the thermal development background and testing, along with details of early flight thermal performance data.

Using Linked Open Data and Semantic Integration to Search Across Geoscience Repositories

NASA Astrophysics Data System (ADS)

Mickle, A.; Raymond, L. M.; Shepherd, A.; Arko, R. A.; Carbotte, S. M.; Chandler, C. L.; Cheatham, M.; Fils, D.; Hitzler, P.; Janowicz, K.; Jones, M.; Krisnadhi, A.; Lehnert, K. A.; Narock, T.; Schildhauer, M.; Wiebe, P. H.

2014-12-01

The MBLWHOI Library is a partner in the OceanLink project, an NSF EarthCube Building Block, applying semantic technologies to enable knowledge discovery, sharing and integration. OceanLink is testing ontology design patterns that link together: two data repositories, Rolling Deck to Repository (R2R), Biological and Chemical Oceanography Data Management Office (BCO-DMO); the MBLWHOI Library Institutional Repository (IR) Woods Hole Open Access Server (WHOAS); National Science Foundation (NSF) funded awards; and American Geophysical Union (AGU) conference presentations. The Library is collaborating with scientific users, data managers, DSpace engineers, experts in ontology design patterns, and user interface developers to make WHOAS, a DSpace repository, linked open data enabled. The goal is to allow searching across repositories without any of the information providers having to change how they manage their collections. The tools developed for DSpace will be made available to the community of users. There are 257 registered DSpace repositories in the United Stated and over 1700 worldwide. Outcomes include: Integration of DSpace with OpenRDF Sesame triple store to provide SPARQL endpoint for the storage and query of RDF representation of DSpace resources, Mapping of DSpace resources to OceanLink ontology, and DSpace "data" add on to provide resolvable linked open data representation of DSpace resources.

Shale Gas in Europe: pragmatic perspectives and actions

NASA Astrophysics Data System (ADS)

Hübner, A.; Horsfield, B.; Kapp, I.

2012-10-01

Natural gas will continue to play a key role in the EU's energy mix in the coming years, with unconventional gas' role increasing in importance as new resources are exploited worldwide. As far as Europe's own shale gas resources are concerned, it is especially the public's perception and level of acceptance that will make or break shale gas in the near-term. Both the pros and cons need to be discussed based on factual argument rather than speculation. Research organizations such as ours (GFZ German Research Centre for Geosciences) have an active and defining role to play in remedying this deficiency. As far as science and technology developments are concerned, the project "Gas Shales in Europe" (GASH) and the shale gas activities of "GeoEnergie" (GeoEn) are the first major initiatives in Europe focused on shale gas. Basic and applied geoscientific research is conducted to understand the fundamental nature and interdependencies of the processes leading to shale gas formation. When it comes to knowledge transfer, the perceived and real risks associated with shale gas exploitation need immediate evaluation in Europe using scientific analysis. To proactively target these issues, the GFZ and partners are launching the European sustainable Operating Practices (E-SOP) Initiative for Unconventional Resources. The web-based Shale Gas Information Platform (SHIP) brings these issues into the public domain.

Earth Observations: Experiences from Various Communication Strategies

NASA Astrophysics Data System (ADS)

Lilja Bye, Bente

2015-04-01

With Earth observations and the Group of Earth Observations as the common thread, a variety of communication strategies have been applied showcasing the use of Earth observations in geosciences such as climate change, natural hazards, hydrology and more. Based on the experiences from these communication strategies, using communication channels ranging from popular articles in established media, video production, event-based material and social media, lessons have been learned both with respect to the need of capacity, skills, networks, and resources. In general it is not difficult to mobilize geoscientists willing to spend some time on outreach activities. Time for preparing and training is however scarce among scientists. In addition, resources to cover the various aspects of professional science outreach is far from abundant. Among the challenges is the connection between the scientific networks and media channels. Social media competence and capacity are also issues that needs to be addressed more explicitly and efficiently. An overview of the experiences from several types of outreach activities will be given along with some input on possible steps towards improved communication strategies. Steady development of science communication strategies continuously integrating trainging of scientists in use of new outreach tools such as web technology and social innovations for more efficient use of limited resources will remain an issue for the scientific community.

How rich is Australia's minerals endowment and is it adequate to sustain a major role in meeting international demand?

NASA Astrophysics Data System (ADS)

Lambert, I. B.

2012-04-01

Dr Ian Lambert, Geoscience Australia and Secretary General 34th International Geological Congress Australia has comparative advantages in production of mineral commodities compared to most other countries. These stem from its rich and diverse mineral endowment; availability of regional scale (pre-competitive) geoscience information to lower the risks of exploration; advances in exploration, mining and processing technologies; skilled work force; generally benign physical conditions; and low population density. Building on these strengths, Australia is a major producer and exporter of a wide range of mineral and energy commodities to global markets. Given that demand for most major commodities is likely to continue, and that there will be growing markets for some other commodities, Australia needs to have a strategic view of what is likely to be available for mining. Further, Australia (and the world) needs to be attuned to issues that need to be faced in meeting international demand for commodities in the long term. This presentation outlines how Australia's national minerals inventory is compiled. It discusses trends for Australia's identified mineral resources for major commodities, and how these compare with other major mining nations. It then considers some significant issues in relation to sustaining a strong mining sector - in the medium to long term this requires a strategic approach to achieve goals such as more effective/lower risk exploration particularly in greenfields regions; well-Informed decisions on mining proposals; ongoing significant improvements in efficiencies of energy, water and land use.

Unidata: Community, Science, and Technology; in that order.

NASA Astrophysics Data System (ADS)

Young, J. W.; Ramamurthy, M. K.; Davis, E.

2015-12-01

Unidata's mission is to provide the data services, tools, and cyberinfrastructure leadership that advance Earth system science, enhance educational opportunities, and broaden participation. The Unidata community has grown from around 250 individual participants in the early years to tens of thousands of users in over 150 countries. Today, Unidata's products and services are used on every continent and by every sector of the geoscience enterprise: universities, government agencies, private sector, and other non-governmental organizations. Certain traits and ethos are shared by and common to most successful organizations. They include a healthy organizational culture grounded by some core values and guiding principles. In that environment, there is an implicit awareness of the connection between mission of an organization, its values, and its day-to-day activities, and behaviours of a passionate staff. Distinguishing characteristics include: vigorous engagement of the community served by those organizations backed by strong and active governance, unwavering commitment to seek input and feedback from users, and trust of those users, earned over many years through consistent, dependable, and high-quality service. Meanwhile, changing data volumes and standards, new computing power, and expanding scientific questions sound continue to shape the geoscience community. These issues were the drivers for founding Unidata, a cornerstone data facility, in 1984. Advances in geoscience occur at the junction of community, science, and technology and this submission will feature lessons from Unidata's thirty year history operating at this nexus. Specifically, this presentation will feature guiding principles for the program, governance mechanisms, and approaches for balancing science and technology in a community-driven program.

Professional Development for Researchers in Solid Earth Science Evolved to Include Scientific and Educational Content

NASA Astrophysics Data System (ADS)

Eriksson, S. C.; Arrowsmith, R.; Olds, S. E.

2011-12-01

Integrated measures of crustal deformation provide valuable insight about tectonic and human-induced processes for scientists and educators alike. UNAVCO in conjunction with EarthScope initiated a series of short courses for researchers to learn the processing and interpretation of data from new technologies such as high precision GPS, Strainmeter, InSar and LiDAR that provide deformation information relevant to many geoscience sub-disciplines. Intensive short courses of a few days and the widespread availability of processed data through large projects such as EarthScope and GEON enable more geoscientists to incorporate these data into diverse projects. Characteristics of the UNAVCO Short Course Series, reaching over 400 participants since 2005, include having short course faculty who have pioneered development of each technology; open web-access to course materials; processing software installed on class-ready computers; no course fees; scholarships for students, post-doctoral fellows, and emerging faculty when needed; formative evaluation of the courses; community-based decisions on topics; and recruitment of participants across relevant geoscience disciplines. In 2009, when EarthScope airborne LiDAR data became available to the public through OpenTopographhy, teaching materials were provided to these researchers to incorporate the latest technologies into teaching. Multiple data sets across technologies have been developed with instructions on how to access the various data sets and incorporate them into geological problem sets. Courses in GPS, airborne LiDAR, strainmeter, and InSAR concentrate on data processing with examples of various geoscience applications. Ground-based LiDAR courses also include data acquisition. Google Earth is used to integrate various forms of data in educational applications. Various types of EarthScope data can now be used by a variety of geoscientists, and the number of scientists who have the skills and tools to use these various datasets has increased. Evaluation data show that participants highly value these courses and are interested in distance learning; however, due to the hands-on nature of processing data and the one-on-one teaching commonly used in these courses, distance learning has been minimal. The diversity of participants is high for the geosciences. The courses also play an important role in increasing the scientific capacity in the international community.

A Unique Partnership to Promote Diversity in the Geosciences, San Jose, California

NASA Astrophysics Data System (ADS)

Sedlock, R.; Metzger, E.; Johnson, D.

2006-12-01

We report here on a particularly satisfying partnership of academic institutions that focuses on enhancing the participation of underrepresented students in the geosciences. The Bay Area Earth Science Institute (BAESI) at San José State University (SJSU) has provided professional development opportunities to over 1,500 area teachers since 1990. BAESI offerings include summer and weekend workshops, field trips, classroom visits, and a lending library of curricula, sample sets, A/V materials, and equipment. The National Hispanic University (NHU) is a private, non-profit university that enrolls about 700 students, 80% of whom are of Hispanic descent. Another 13% are from other minority groups, 74% are from low-income families, and 70% are women. NHU houses the Latino College Preparatory Academy (LCPA), a charter high school that provides an alternative for students who struggle in traditional schools due to language issues. In the 1990s, administrators at SJSU and NHU set up formal agreements about course articulation, reciprocity, and joint degree programs. In 2002, informal discussions between BAESI and NHU staff led to collaboration on an NSF proposal to strengthen NHU's geoscience curriculum. Since then, the scope of BAESI-NHU actions has expanded greatly: (1) NHU and LCPA staff attended a week-long BAESI professional development workshop funded by NSF, and have attended numerous BAESI field trips. (2) BAESI staff visit NHU and LCPA classrooms to showcase SJSU's Geology Department and to enrich existing Chemistry and Physics classes with geoscience applications. (3) A nascent "Geologist-In-Residence" program pairs SJSU geology students with teachers at LCPA. (4) NHU students have interned with Metzger on local research projects. (5) BAESI brokered donation of an extensive USGS rock collection to NHU. (6) NHU, BAESI, and NASA-Ames staff collaborate on an online Earth Science curriculum for middle-school teachers. (7) We will adapt BAESI summer workshops to a one-week course in effective teaching of high-school science that will be taught during intersession in NHU's Teacher Education Department. We have recently received funding for a collaborative project from NSF's Geoscience Education program to create a joint degree program wherein NHU offers the lower division coursework and bestows an A.S. degree in mathematics and science with geoscience emphasis, and SJSU offers the upper-division coursework and the B.S. degree in geoscience. Our collaborations focus on providing teachers with professional development and educational resources to help underrepresented students receive quality instruction in the geosciences. Participation of NHU teachers- in-training provides a long-term means for spreading quality geoscience teaching to precollege classrooms throughout Santa Clara County, including the largely minority classrooms that NHU teachers are specially trained to staff.

AMIDST: Attracting Minorities to Geosciences Through Involved Digital Story Telling

NASA Astrophysics Data System (ADS)

Prakash, A.; Ohler, J.; Cooper, C.; McDermott, M.; Heinrich, J.; Johnson, R.; Leeper, L.; Polk, N.; Wimer, T.

2009-12-01

Attracting Minorities to Geosciences Through Involved Digital Story Telling (AMIDST) is a project funded by the Geoscience Directorate of the National Science Foundation through their program entitled Opportunities for Enhancing Diversity in Geosciences. This project centers around the idea of integrating place-based geoscience education with culturally sensitive digital story telling, to engage and attract Alaska’s native and rural children from grades 3 through 5 to geosciences. In Spring 2008 we brought together a team 2 native elders, a group of scientists and technicians, an evaluator, 2 teachers and their 24 third grade students from Fairbanks (interior Alaska) to create computer-based digital stories around the geoscience themes of permafrost, and forest fires. These two to four minutes digital narratives consisted of a series of images accompanied by music and a voice-over narration by the children. In Fall 2008 we worked with a similar group from Nome (coastal town in western Alaska). The geoscience themes were climate change, and gold in Alaska. This time the students used the same kind of “green screen” editing so prevalent in science fiction movies. Students enacted and recorded their stories in front of a green screen and in post-production replaced the green background with photos, drawings and scientific illustrations related to their stories. Evaluation involved pre and post project tests for all participants, mid-term individual interviews and exit-interviews of selected participants. Project final assessment results from an independent education evaluator showed that both students and teachers improved their geo science content knowledge about permafrost, forest fires, gold mining, and sea ice changes. Teachers and students went through a very steep learning curve and gained experience and new understanding in digital storytelling in the context of geologic phenomena of local interest. Children took pride in being creators, directors and editors of their own stories. We also concluded that the proposed idea is an excellent hook to intrigue children to science and technology in general, but demands time and commitment from the involved participants. Given the time constraints of a class environment future efforts would be best if spread over a year rather than one semester, or if implemented during summer programs that offer more time and flexibility.

An infrastructure for the integration of geoscience instruments and sensors on the Grid

NASA Astrophysics Data System (ADS)

Pugliese, R.; Prica, M.; Kourousias, G.; Del Linz, A.; Curri, A.

2009-04-01

The Grid, as a computing paradigm, has long been in the attention of both academia and industry[1]. The distributed and expandable nature of its general architecture result to scalability and more efficient utilisation of the computing infrastructures. The scientific community, including that of geosciences, often handles problems with very high requirements in data processing, transferring, and storing[2,3]. This has raised the interest on Grid technologies but these are often viewed solely as an access gateway to HPC. Suitable Grid infrastructures could provide the geoscience community with additional benefits like those of sharing, remote access and control of scientific systems. These systems can be scientific instruments, sensors, robots, cameras and any other device used in geosciences. The solution for practical, general, and feasible Grid-enabling of such devices requires non-intrusive extensions on core parts of the current Grid architecture. We propose an extended version of an architecture[4] that can serve as the solution to the problem. The solution we propose is called Grid Instrument Element (IE) [5]. It is an addition to the existing core Grid parts; the Computing Element (CE) and the Storage Element (SE) that serve the purposes that their name suggests. The IE that we will be referring to, and the related technologies have been developed in the EU project on the Deployment of Remote Instrumentation Infrastructure (DORII1). In DORII, partners of various scientific communities including those of Earthquake, Environmental science, and Experimental science, have adopted the technology of the Instrument Element in order to integrate to the Grid their devices. The Oceanographic and coastal observation and modelling Mediterranean Ocean Observing Network (OGS2), a DORII partner, is in the process of deploying the above mentioned Grid technologies on two types of observational modules: Argo profiling floats and a novel Autonomous Underwater Vehicle (AUV). In this paper i) we define the need for integration of instrumentation in the Grid, ii) we introduce the solution of the Instrument Element, iii) we demonstrate a suitable end-user web portal for accessing Grid resources, iv) we describe from the Grid-technological point of view the process of the integration to the Grid of two advanced environmental monitoring devices. References [1] M. Surridge, S. Taylor, D. De Roure, and E. Zaluska, "Experiences with GRIA—Industrial Applications on a Web Services Grid," e-Science and Grid Computing, First International Conference on e-Science and Grid Computing, 2005, pp. 98-105. [2] A. Chervenak, I. Foster, C. Kesselman, C. Salisbury, and S. Tuecke, "The data grid: Towards an architecture for the distributed management and analysis of large scientific datasets," Journal of Network and Computer Applications, vol. 23, 2000, pp. 187-200. [3] B. Allcock, J. Bester, J. Bresnahan, A.L. Chervenak, I. Foster, C. Kesselman, S. Meder, V. Nefedova, D. Quesnel, and S. Tuecke, "Data management and transfer in high-performance computational grid environments," Parallel Computing, vol. 28, 2002, pp. 749-771. [4] E. Frizziero, M. Gulmini, F. Lelli, G. Maron, A. Oh, S. Orlando, A. Petrucci, S. Squizzato, and S. Traldi, "Instrument Element: A New Grid component that Enables the Control of Remote Instrumentation," Proceedings of the Sixth IEEE International Symposium on Cluster Computing and the Grid (CCGRID'06)-Volume 00, IEEE Computer Society Washington, DC, USA, 2006. [5] R. Ranon, L. De Marco, A. Senerchia, S. Gabrielli, L. Chittaro, R. Pugliese, L. Del Cano, F. Asnicar, and M. Prica, "A Web-based Tool for Collaborative Access to Scientific Instruments in Cyberinfrastructures." 1 The DORII project is supported by the European Commission within the 7th Framework Programme (FP7/2007-2013) under grant agreement no. RI-213110. URL: http://www.dorii.eu 2 Istituto Nazionale di Oceanografia e di Geofisica Sperimentale. URL: http://www.ogs.trieste.it

Virtual Geophysics Laboratory: Exploiting the Cloud and Empowering Geophysicsts

NASA Astrophysics Data System (ADS)

Fraser, Ryan; Vote, Josh; Goh, Richard; Cox, Simon

2013-04-01

Over the last five decades geoscientists from Australian state and federal agencies have collected and assembled around 3 Petabytes of geoscience data sets under public funding. As a consequence of technological progress, data is now being acquired at exponential rates and in higher resolution than ever before. Effective use of these big data sets challenges the storage and computational infrastructure of most organizations. The Virtual Geophysics Laboratory (VGL) is a scientific workflow portal addresses some of the resulting issues by providing Australian geophysicists with access to a Web 2.0 or Rich Internet Application (RIA) based integrated environment that exploits eResearch tools and Cloud computing technology, and promotes collaboration between the user community. VGL simplifies and automates large portions of what were previously manually intensive scientific workflow processes, allowing scientists to focus on the natural science problems, rather than computer science and IT. A number of geophysical processing codes are incorporated to support multiple workflows. For example a gravity inversion can be performed by combining the Escript/Finley codes (from the University of Queensland) with the gravity data registered in VGL. Likewise, tectonic processes can also be modeled by combining the Underworld code (from Monash University) with one of the various 3D models available to VGL. Cloud services provide scalable and cost effective compute resources. VGL is built on top of mature standards-compliant information services, many deployed using the Spatial Information Services Stack (SISS), which provides direct access to geophysical data. A large number of data sets from Geoscience Australia assist users in data discovery. GeoNetwork provides a metadata catalog to store workflow results for future use, discovery and provenance tracking. VGL has been developed in collaboration with the research community using incremental software development practices and open source tools. While developed to provide the geophysics research community with a sustainable platform and scalable infrastructure; VGL has also developed a number of concepts, patterns and generic components of which have been reused for cases beyond geophysics, including natural hazards, satellite processing and other areas requiring spatial data discovery and processing. Future plans for VGL include a number of improvements in both functional and non-functional areas in response to its user community needs and advancement in information technologies. In particular, research is underway in the following areas (a) distributed and parallel workflow processing in the cloud, (b) seamless integration with various cloud providers, and (c) integration with virtual laboratories representing other science domains. Acknowledgements: VGL was developed by CSIRO in collaboration with Geoscience Australia, National Computational Infrastructure, Australia National University, Monash University and University of Queensland, and has been supported by the Australian Government's Education Investment Funds through NeCTAR.

Hybrid Cloud Computing Environment for EarthCube and Geoscience Community

NASA Astrophysics Data System (ADS)

Yang, C. P.; Qin, H.

2016-12-01

The NSF EarthCube Integration and Test Environment (ECITE) has built a hybrid cloud computing environment to provides cloud resources from private cloud environments by using cloud system software - OpenStack and Eucalyptus, and also manages public cloud - Amazon Web Service that allow resource synchronizing and bursting between private and public cloud. On ECITE hybrid cloud platform, EarthCube and geoscience community can deploy and manage the applications by using base virtual machine images or customized virtual machines, analyze big datasets by using virtual clusters, and real-time monitor the virtual resource usage on the cloud. Currently, a number of EarthCube projects have deployed or started migrating their projects to this platform, such as CHORDS, BCube, CINERGI, OntoSoft, and some other EarthCube building blocks. To accomplish the deployment or migration, administrator of ECITE hybrid cloud platform prepares the specific needs (e.g. images, port numbers, usable cloud capacity, etc.) of each project in advance base on the communications between ECITE and participant projects, and then the scientists or IT technicians in those projects launch one or multiple virtual machines, access the virtual machine(s) to set up computing environment if need be, and migrate their codes, documents or data without caring about the heterogeneity in structure and operations among different cloud platforms.

Metal mining and the environment

USGS Publications Warehouse

Hudson, Travis L.; Fox, Frederick D.; Plumlee, Geoffrey S.

1999-01-01

The booklet, Metal Mining and the Environment, and the colorful companion poster offer new tools for raising awareness and understanding of the impact and issues surrounding metal mining and the environment. The 64-page full-color booklet contains a copy of the poster which includes a student activity on the back. This booklet and poster can help you: illustrate the importance of our natural and environmental resources; provide a geoscience perspective on metal mining and the environment; improve Earth science literacy; and increase student understandings of Earth resources and systems.

Rocks, Landforms, and Landscapes vs. Words, Sentences, and Paragraphs: An Interdisciplinary Team Approach to Teaching the Tie Between Scientific Literacy and Inquiry-based Writing in a Community College's Geoscience Program and a University's' Geoscience Program

NASA Astrophysics Data System (ADS)

Thweatt, A. M.; Giardino, J. R.; Schroeder, C.

2014-12-01

Scientific literacy and inquiry-based writing go together like a hand and glove. Science literacy, defined by NRC in The NSF Standards, stresses the relationship between knowledge of science and skill in literacy so "a person can ask, find, or determine answers to questions derived from curiosity about everyday experiences. It means that a person has the ability to describe, explain, and predict natural phenomena. Scientific literacy entails being able to read with understanding articles about science in the popular press and to engage in social conversation about the validity of the conclusions. Scientific literacy implies that a person can identify scientific issues underlying national and local decisions and express positions that are scientifically and technologically informed." A growing body of research and practice in science instruction suggests language is essential in the practice of the geosciences. Writing and critical thinking are iterative processes. We use this approach to educate our geoscience students to learn, write, and think critically. One does not become an accomplished writer via one course. Proficiency is gained through continued exposure, guidance and tailored assignments. Inquiry-based geoscience makes students proficient in the tools of the geosciences and to develop explanations to questions about Earth events. We have scaffolded our courses from introductory geology, English composition, writing in the geosciences, introduction to field methods and report writing to do more critical thinking, research data gatherings, and in-depth analysis and synthesis. These learning experiences that encourage students to compare their reasoning models, communicate verbally, written and graphically. The English composition course sets the stage for creative assignments through formulation of original research questions, collection of primary data, analysis, and construction of written research papers. Proper use of language allows students to clarify their ideas, make claims, present arguments, and record and present findings. Students have acquired the skills to be considered scientifically literate and capable of learning. A poster demonstrating the tie between Scientific Literacy and Inquiry-Based Writing has been produced and distributed widely around campus.

Building a Community for Art and Geoscience

NASA Astrophysics Data System (ADS)

Eriksson, S. C.; Ellins, K. K.

2014-12-01

Several new avenues are in place for building and supporting a community of people interested in the art and geoscience connections. Although sessions advocating for art in teaching geoscience have been scattered through geoscience professional meetings for several decades, there is now a sustained presence of artists and geoscientists with their research and projects at the annual meeting of the American Geophysical Union. In 2011, 13 abstracts were submitted and, in 2013, 20 talks and posters were presented at the annual meeting. Participants have requested more ways to connect with each other as well as advocate for this movement of art and science to others. Several words can describe new initiatives to do this: Social, Collaborative, Connected, Informed, Networked, and Included. Social activities of informal dinners, lunches, and happy hour for interested people in the past year have provided opportunity for presenters at AGU to spend time getting to know one another. This has resulted in at least two new collaborative projects. The nascent Bella Roca and more established Geology in Art websites and their associated blogs at www.bellaroca.org and http://geologyinart.blogspot.com, respectively are dedicated to highlighting the work of artists inspired by the geosciences, connecting people and informing the community of exhibits and opportunities for collaboration. Bella Roca with its social media of Facebook (Bella Roca) and Twitter (@BellRocaGeo), is a direct outgrowth of the recent 2012 and 2013 AGU sessions and, hopefully, can be grown and sustained for this community. Articles in professional journals will also help inform the broader geoscience community of the benefit of engaging with artists and designers for both improved science knowledge and communication. Organizations such as Leonardo, the International Society for the Arts, Sciences and Technology, the Art Science Gallery in Austin, Texas also promote networking among artists and scientists with the aim of helping to build new transdisciplinary projects that both engage the public and advance science and art. The inclusion of art/science scholars and practitioners in organizations such as AGU and others will provide visibility, endorsement, and support as new projects are formulated for the benefit of both art and geoscience.

Diversity and Equity in Environmental Organizations: The Salience of These Factors to Students

ERIC Educational Resources Information Center

Taylor, Dorceta E.

2007-01-01

Diversity in environmental institutions is of increasing concern to scholars and practitioners. The author examined student perceptions of the importance of 20 diversity and equity factors in their decisions to accept a job. A national sample of 1,239 students in 9 environmental disciplines (biological sciences, geosciences, natural resources,…

Through the Lens of TEK - Building GeoScience Pathways for American Indian/Alaska Native Students

NASA Astrophysics Data System (ADS)

Thomas, W. J.; van Cooten, S.; Wrege, B.; Wildcat, D.

2017-12-01

Native American or American Indian/Alaska Native (AI/AN) students come from diverse communities with indigenous knowledges, perspectives and worldviews. These communities and the students they send into our nation's education systems have cultural connectivity to oral histories, documents, and artwork that details climate cycles and weather events prior to colonization through eras of forced relocation and assimilation. Today, these students are the trailblazers as tribal governments exercise their ownership rights to natural resources and the welfare of their citizens as sovereign nations. In universities, especially tribal colleges, our nation's indigenous students are bridge builders. Through the lens of Traditional Ecological Knowledge (TEK), these students have a unique yet overlooked perspective to merge mainstream research with indigenous knowledge systems to develop practical sustainable solutions for local, regional and international resource management issues. The panel will discuss barriers, such as underdeveloped geophysical science curricula at tribal colleges, that limit the pool of indigenous geoscience graduates and examine possible strategies such as entry point opportunities and partnerships, mentoring, and community relevant research experiences, to eliminate barriers that limit the influx of TEK in resiliency planning.

Exploring Student-to-Workforce Transitions with the National Geoscience Exit Survey

NASA Astrophysics Data System (ADS)

Gonzales, L. M.; Keane, C. M.; Houlton, H. R.

2011-12-01

In 2011, the American Geological Institute (AGI) launched the first pilot of a National Geoscience Exit Survey in collaboration with 32 geoscience university departments. The survey collects data about demographics, high school and community college coursework, university degrees, financial aid, field and research experiences, internships, and when and why the student chose to pursue a geosciences degree. Additionally, the survey collects information about students' future academic and career plans, and gives participants the option to take part in a longitudinal survey to track long-term career trajectories of geosciences graduates. The survey also provides geoscience departments with the ability to add customized questions to collect data about important departmental-level topics. The National Geoscience Exit Survey will be available to all U.S. geoscience programs at two- and four-year colleges and universities by the end of the 2011-2012 academic year. We use the results of the National Geoscience Exit Survey to examine student preparation and transition into geosciences and non-geoscience careers. Preliminary results from the pilot survey indicated future academic and career trajectories for geoscience Bachelor's degree recipients included graduate school (53%) and pursuit of a geoscience career (45%), with some undergraduates keeping their options open for either trajectory. Twelve percent of Bachelor's degree recipients already accepted job offers with geoscience employers. For geoscience Master's degree recipients, 17% planned to continue in graduate school, 35% were seeking a geoscience job, and 42% had already accepted job offers with geoscience employers. Furthermore, the majority of those geoscience graduates who already accepted geoscience job offers had also interned previously with the employer.

Porphyry Copper Deposits of the World: Database and Grade and Tonnage Models, 2008

USGS Publications Warehouse

Singer, Donald A.; Berger, Vladimir I.; Moring, Barry C.

2008-01-01

This report is an update of earlier publications about porphyry copper deposits (Singer, Berger, and Moring, 2002; Singer, D.A., Berger, V.I., and Moring, B.C., 2005). The update was necessary because of new information about substantial increases in resources in some deposits and because we revised locations of some deposits so that they are consistent with images in GoogleEarth. In this report we have added new porphyry copper deposits and removed a few incorrectly classed deposits. In addition, some errors have been corrected and a number of deposits have had some information, such as grades, tonnages, locations, or ages revised. Colleagues have helped identify places where improvements were needed. Mineral deposit models are important in exploration planning and quantitative resource assessments for a number of reasons including: (1) grades and tonnages among deposit types are significantly different, and (2) many types occur in different geologic settings that can be identified from geologic maps. Mineral deposit models are the keystone in combining the diverse geoscience information on geology, mineral occurrences, geophysics, and geochemistry used in resource assessments and mineral exploration. Too few thoroughly explored mineral deposits are available in most local areas for reliable identification of the important geoscience variables or for robust estimation of undiscovered deposits?thus we need mineral-deposit models. Globally based deposit models allow recognition of important features because the global models demonstrate how common different features are. Well-designed and -constructed deposit models allow geologists to know from observed geologic environments the possible mineral deposit types that might exist, and allow economists to determine the possible economic viability of these resources in the region. Thus, mineral deposit models play the central role in transforming geoscience information to a form useful to policy makers. The foundation of mineral deposit models is information about known deposits. The purpose of this publication is to make this kind of information available in digital form for porphyry copper deposits. The consistently defined deposits in this file provide the foundation for grade and tonnage models included here and for mineral deposit density models (Singer and others, 2005: Singer, 2008).

Roadmap for Developing of Brokering as a Component of EarthCube

NASA Astrophysics Data System (ADS)

Pearlman, J.; Khalsa, S. S.; Browdy, S.; Duerr, R. E.; Nativi, S.; Parsons, M. A.; Pearlman, F.; Robinson, E. M.

2012-12-01

The goal of NSF's EarthCube is to create a sustainable infrastructure that enables the sharing of all geosciences data, information, and knowledge in an open, transparent and inclusive manner. Key to achieving the EarthCube vision is establishing a process that will guide the evolution of the infrastructure through community engagement and appropriate investment so that the infrastructure is embraced and utilized by the entire geosciences community. In this presentation we describe a roadmap, developed through the EarthCube Brokering Concept Award, for an evolutionary process of infrastructure and interoperability development. All geoscience communities already have, to a greater or lesser degree, elements of an information infrastructure in place. These elements include resources such as data archives, catalogs, and portals as well as vocabularies, data models, protocols, best practices and other community conventions. What is necessary now is a process for consolidating these diverse infrastructure elements into an overall infrastructure that provides easy discovery, access and utilization of resources across disciplinary boundaries. This process of consolidation will be achieved by creating "interfaces," what we call "brokers," between systems. Brokers connect disparate systems without imposing new burdens upon those systems, and enable the infrastructure to adjust to new technical developments and scientific requirements as they emerge. Robust cyberinfrastructure will arise only when social, organizational, and cultural issues are resolved in tandem with the creation of technology-based services. This is best done through use-case-driven requirements and agile, iterative development methods. It is important to start by solving real (not hypothetical) information access and use problems via small pilot projects that develop capabilities targeted to specific communities. These pilots can then grow into larger prototypes addressing intercommunity problems working towards a full-scale socio-technical infrastructure vision. Brokering, as a critical capability for connecting systems, evolves over time through more connections and increased functionality. This adaptive process allows for continual evaluation as to how well science-driven use cases are being met. Several NSF infrastructure projects are underway and beginning to shape the next generation of information sharing. There is a near term, and possibly unique, opportunity to increase the impact and interconnectivity of these projects, and further improve science research collaboration through brokering. Brokering has been demonstrated to be an essential part of a robust, adaptive infrastructure, but critical questions of governance and detailed implementation remain. Our roadmap proposes the expansion of brokering pilots into fully operational prototypes that work with the broader science and informatics communities to answer these questions, connect existing and emerging systems, and evolve the EarthCube infrastructure.

Insights on WWW-based geoscience teaching: Climbing the first year learning cliff

NASA Astrophysics Data System (ADS)

Lamberson, Michelle N.; Johnson, Mark; Bevier, Mary Lou; Russell, J. Kelly

1997-06-01

In early 1995, The University of British Columbia Department of Geological Sciences (now Earth and Ocean Sciences) initiated a project that explored the effectiveness of the World Wide Web as a teaching and learning medium. Four decisions made at the onset of the project have guided the department's educational technology plan: (1) over 90% of funding recieved from educational technology grants was committed towards personnel; (2) materials developed are modular in design; (3) a data-base approach was taken to resource development; and (4) a strong commitment to student involvement in courseware development. The project comprised development of a web site for an existing core course: Geology 202, Introduction to Petrology. The web site is a gateway to course information, content, resources, exercises, and several searchable data-bases (images, petrologic definitions, and minerals in thin section). Material was developed on either an IBM or UNIX machine, ported to a UNIX platform, and is accessed using the Netscape browser. The resources consist primarily of HTML files or CGI scripts with associated text, images, sound, digital movies, and animations. Students access the web site from the departmental student computer facility, from home or a computer station in the petrology laboratory. Results of a survey of the Geol 202 students indicate that they found the majority of the resources useful, and the site is being expanded. The Geology 202 project had a "trickle-up" effect throughout the department: prior to this project, there was minimal use of Internet resources in lower-level geology courses. By the end of the 1996-1997 academic year, we anticipate that at least 17 Earth and Ocean Science courses will have a WWW site for one or all of the following uses: (1) presenting basic information; (2) accessing lecture images; (3) providing a jumping-off point for exploring related WWW sites; (4) conducting on-line exercises; and/or (5) providing a communications forum for students and faculty via a Hypernews group. Url http://www.science.ubc.ca/

Supporting Implementation of the Next Generation Science Standards: A Needs Assessment Outline

NASA Astrophysics Data System (ADS)

Sullivan, S. M.; Robeck, E.; Awad, A. A.

2015-12-01

The Next Generation Science Standards (NGSS) explicitly treat Earth and Space Science (ESS) content with the same level of priority as Physical Science, Life Science, and Engineering & Technology. Therefore, the geoscience community has a vested interest in the use of NGSS as it is being implemented in K-12 classrooms. Individuals and groups from all facets of the geosciences can take action to support the implementation of the NGSS. That action will be most effective if it is guided by a thorough understanding of the needs of teachers and other stakeholders who have a role to play in NGSS implementation. This session will describe qualitative and quantitative needs assessment data that was gathered in advance of the Summit Meeting on the Implementation of the NGSS at the State Level, which was jointly organized in April 2015 by the American Geosciences Institute (AGI) and the National Association of Geoscience Teachers (NAGT). The data to be discussed are from interviews and quantitative survey data, as well as data based on responses by the 50+ Summit attendees who represented a variety of perspectives in geoscience education. Particular attention will be given to areas where responses suggested points of tension, such as the fact that many survey respondents feel that they understand dimensions of the NGSS that their colleagues do not understand as well, making for a potentially difficult context in which to work to implement the NGSS. Actions suggested by the Summit attendees that are related to the different need areas will also be described, with the intent being to open discussion among session participants about additional actions that they can take individually and/or collectively. The overarching goal of this presentation will be to work in coordination with the other presentations in the session to expand the network of member of the geoscience community who are informed and committed to supporting NGSS implementation.

Mississippi State University’s Geoscience Education and Geocognition Research Program in the Department of Geosciences

NASA Astrophysics Data System (ADS)

McNeal, K.; Clary, R. M.; Sherman-Morris, K.; Kirkland, B.; Gillham, D.; Moe-Hoffman, A.

2009-12-01

The Department of Geosciences at Mississippi State University offers both a MS in Geosciences and a PhD in Earth and Atmospheric Sciences, with the possibility of a concentration in geoscience education. The department offers broad research opportunities in the geoscience sub-disciplines of Geology, Meteorology, GIS, and Geography. Geoscience education research is one of the research themes emphasized in the department and focuses on geoscience learning in traditional, online, field-based, and informal educational environments. Approximately 20% of the faculty are actively conducting research in geoscience education and incorporate both qualitative and quantitative research approaches in areas including: the investigation of effective teaching strategies, the implementation and evaluation of geoscience teacher professional development programs and diversity enhancement programs, the study of the history and philosophy of science in geoscience teaching, the exploration of student cognition and understanding of complex and dynamic earth systems, and the investigation of using visualizations to enhance learning in the geosciences. The inception and continued support of an active geoscience education research program is derived from a variety of factors including: (1) the development of the on-line Teachers in Geosciences (TIG) Masters Degree Program which is the primary teaching appointment for the majority of the faculty conducting geoscience education research, (2) the securing of federal funds to support geoscience education research, (3) the publication of high-quality peer-reviewed research papers in both geoscience education and traditional research domains, (4) the active contribution of the geoscience education faculty in their traditional research domains, (5) a faculty that greatly values teaching and recognizes the research area of geoscience education as a sub-domain of the broader geoscience disciplines, (6) the involvement of university faculty, outside of these primary faculty leaders, in geoscience education research-related projects where the expertise the geoscience education faculty offers is a catalyst for collaboration, (7) departmental support including research space, teaching loads, and start-up funds that are in-line with the remainder of the department faculty. Results of the program have included securing funding from multiple agencies (e.g., NSF, NASA, DOE, MDE, NOAA, ARC), providing support to and involving graduate and undergraduate students in both geoscience education and traditional research projects, disseminating project results in peer-reviewed journals, technical reports, and international/national conferences, and developing courses for the concentration in geoscience education.

The British Geological Survey and the petroleum industry

DOE Office of Scientific and Technical Information (OSTI.GOV)

Chesher, J.A.

1995-08-01

The British Geological Survey is the UK`s national centre for earth science information with a parallel remit to operate internationally. The Survey`s work covers the full geoscience spectrum in energy, mineral and groundwater resources and associated implications for land use, geological hazards and environmental impact. Much of the work is conducted in collaboration with industry and academia, including joint funding opportunities. Activities relating directly to hydrocarbons include basin analysis, offshore geoscience mapping, hazard assessment, fracture characterization, biostratigraphy, sedimentology, seismology, geomagnetism and frontier data acquisition techniques, offshore. The BGS poster presentation illustrates the value of the collaborative approach through consortia supportmore » for regional offshore surveys, geotechnical hazard assessments and state-of-the-art R & D into multicomponent seismic imaging techniques, among others.« less

Enabling Global Collaboration in the Geosciences

NASA Astrophysics Data System (ADS)

Klump, Jens; Allison, Lee; Asch, Kristine; Fox, Peter; Gundersen, Linda; Jackson, Ian; Loewe, Peter; Snyder, Walter S.; Ritschel, Bernd

2008-12-01

Geoinformatics 2008; Potsdam, Germany, 11-13 June 2008; Scientists are facing an increasing flood of data and information in the Earth sciences from which they try to distill knowledge. The emerging discipline of geoinformatics brings together the tools necessary to create and make accessible the knowledge needed to respond to society's complex challenges, such as climate change, new energy and mineral resources, new sources of water, and protecting environmental and human health. Globalization of geoinformatics-based research and education in support of meeting societal challenges was the theme for the Geoinformatics 2008 conference, which was held at the German Research Centre for Geosciences, in Potsdam, Germany. Participants came from China, France, Germany, Japan, Netherlands, Russia, Switzerland, the United Kingdom, and the United States, representing academic institutions, national research centers, and government agencies.

Establishing MICHCARB, a geological carbon sequestration research and education center for Michigan, implemented through the Michigan Geological Repository for Research and Education, part of the Department of Geosciences at Western Michigan University

DOE Office of Scientific and Technical Information (OSTI.GOV)

Barnes, David A.; Harrison, William B.

The Michigan Geological Repository for Research and Education (MGRRE), part of the Department of Geosciences at Western Michigan University (WMU) at Kalamazoo, Michigan, established MichCarb—a geological carbon sequestration resource center by: • Archiving and maintaining a current reference collection of carbon sequestration published literature • Developing statewide and site-specific digital research databases for Michigan’s deep geological formations relevant to CO2 storage, containment and potential for enhanced oil recovery • Producing maps and tables of physical properties as components of these databases • Compiling all information into a digital atlas • Conducting geologic and fluid flow modeling to address specific predictivemore » uses of CO2 storage and enhanced oil recovery, including compiling data for geological and fluid flow models, formulating models, integrating data, and running the models; applying models to specific predictive uses of CO2 storage and enhanced oil recovery • Conducting technical research on CO2 sequestration and enhanced oil recovery through basic and applied research of characterizing Michigan oil and gas and saline reservoirs for CO2 storage potential volume, injectivity and containment. Based on our research, we have concluded that the Michigan Basin has excellent saline aquifer (residual entrapment) and CO2/Enhanced oil recovery related (CO2/EOR; buoyant entrapment) geological carbon sequestration potential with substantial, associated incremental oil production potential. These storage reservoirs possess at least satisfactory injectivity and reliable, permanent containment resulting from associated, thick, low permeability confining layers. Saline aquifer storage resource estimates in the two major residual entrapment, reservoir target zones (Lower Paleozoic Sandstone and Middle Paleozoic carbonate and sandstone reservoirs) are in excess of 70-80 Gmt (at an overall 10% storage efficiency factor; an approximately P50 probability range for all formations using DOE-NETL, 2010, storage resource estimation methodology). Incremental oil production resulting from successful implementation of CO2/EOR for the highest potential Middle Paleozoic reef reservoirs (Silurian, Northern Niagaran Reef trend) in Michigan is estimated at 130 to over 200 MMBO (22-33 Mm3). In addition, between 200 and 400 Mmt of CO2 could be sequestered in the course of successful deployment of CO2/EOR in the northern reef trend’s largest depleted (primary production) oil fields (those that have produced in excess of 500,000 BO; 80,000 m3of oil). • Effecting technology transfer to members of industry and governmental agencies by establishing an Internet Website at which all data, reports and results are accessible; publishing results in relevant journals; conducting technology transfer workshops as part of our role as the Michigan Center of the Petroleum Technology Transfer Council or any successor organization.« less

The Role of Virtual Globes in Geoscience

NASA Technical Reports Server (NTRS)

Bailey, John E.; Chen, Aijun

2011-01-01

One of the difficulties faced by Earth scientists of all disciplines is how to effectively communicate their research to both other scientists and the general public. With increased attention paid to the health of the planet, the activities of geoscientists in particular are falling under the spotlight of public interest. In age where the internet availability has brought an expectation of information being instantly visible in a graphically rich format, the development of Virtual Globes --computer-based representations of the real-world--has become a natural progression for how best to view these data. In this special issue we bring together a cross-selection of the many examples of how Virtual Globe technologies are being used for geoscience.

Strategic Roadmap for the U.S. Geoscience Information Network

NASA Astrophysics Data System (ADS)

Allison, M. L.; Gallagher, K. T.; Richard, S. M.; Hutchison, V. B.

2012-04-01

An external advisory working group has prepared a 5-year strategic roadmap for the U.S. Geoscience Information Network (USGIN). USGIN is a partnership of the Association of American State Geologists (AASG) and the U.S. Geological Survey (USGS), who formally agreed in 2007 to develop a national geoscience information framework that is distributed, interoperable, uses open source standards and common protocols, respects and acknowledges data ownership, fosters communities of practice to grow, and develops new Web services and clients. The intention of the USGIN is to benefit the geological surveys by reducing the cost of online data publication and access provision, and to benefit society through easier (lower cost) access to public domain geoscience data. This information supports environmental planning, resource-development, hazard mitigation design, and decision-making. USGIN supposes that sharing resources for system development and maintenance, standardizing data discovery and creating better access mechanisms, causes cost of data access and maintenance to be reduced. Standardization in a wide variety of business domains provides economic benefits that range between 0.2 and 0.9% of the gross national product. We suggest that the economic benefits of standardization also apply in the informatics domain. Standardized access to rich data resources will create collaborative opportunities in science and business. Development and use of shared protocols and interchange formats for data publication will create a market for user applications, facilitating geoscience data discovery and utility for the benefit of society. The USGIN Working Group envisions further development of tools and capabilities, in addition to extending the community of practice that currently involves geoinformatics practitioners from the USGS and AASG. Promoting engagement and participation of the state geological surveys, and increasing communication between the states, USGS, and other stakeholders are prerequisites for community development. A key element of community building is personal interaction. The USGIN community can establish an identity for geological survey informatics practitioners, can assist in prioritizing technical development that is specific to the geological survey community, and can leverage development taking place in the larger community. Policies, protocols, and procedures for developing, reviewing, and distributing specifications can be adopted from established practices developed by existing organizations, such as the OGC. Documenting and promoting best practices through demonstrations, education, and outreach within the geological survey community is paramount for fostering deployment of interoperable services for data discovery and distribution. Evolution of the current Balkanized geoinformatics practice into a more cohesive and effective community has been and will continue to be an incremental process. The role of USGIN as an entity in this larger community requires organization, planning, promotion, and funding. As a member of a community activity, the role of USGIN as a leader in the community must be organic and emergent. Essential implementation activities include: • Establish a long-term governance model • Develop a business model • Explore testbed opportunities • Develop marketing strategy

Supporting geoscience with graphical-user-interface Internet tools for the Macintosh

NASA Astrophysics Data System (ADS)

Robin, Bernard

1995-07-01

This paper describes a suite of Macintosh graphical-user-interface (GUI) software programs that can be used in conjunction with the Internet to support geoscience education. These software programs allow science educators to access and retrieve a large body of resources from an increasing number of network sites, taking advantage of the intuitive, simple-to-use Macintosh operating system. With these tools, educators easily can locate, download, and exchange not only text files but also sound resources, video movie clips, and software application files from their desktop computers. Another major advantage of these software tools is that they are available at no cost and may be distributed freely. The following GUI software tools are described including examples of how they can be used in an educational setting: ∗ Eudora—an e-mail program ∗ NewsWatcher—a newsreader ∗ TurboGopher—a Gopher program ∗ Fetch—a software application for easy File Transfer Protocol (FTP) ∗ NCSA Mosaic—a worldwide hypertext browsing program. An explosive growth of online archives currently is underway as new electronic sites are being added continuously to the Internet. Many of these resources may be of interest to science educators who learn they can share not only ASCII text files, but also graphic image files, sound resources, QuickTime movie clips, and hypermedia projects with colleagues from locations around the world. These powerful, yet simple to learn GUI software tools are providing a revolution in how knowledge can be accessed, retrieved, and shared.

NADM Conceptual Model 1.0 -- A Conceptual Model for Geologic Map Information

USGS Publications Warehouse

,

2004-01-01

Executive Summary -- The NADM Data Model Design Team was established in 1999 by the North American Geologic Map Data Model Steering Committee (NADMSC) with the purpose of drafting a geologic map data model for consideration as a standard for developing interoperable geologic map-centered databases by state, provincial, and federal geological surveys. The model is designed to be a technology-neutral conceptual model that can form the basis for a web-based interchange format using evolving information technology (e.g., XML, RDF, OWL), and guide implementation of geoscience databases in a common conceptual framework. The intended purpose is to allow geologic information sharing between geologic map data providers and users, independent of local information system implementation. The model emphasizes geoscience concepts and relationships related to information presented on geologic maps. Design has been guided by an informal requirements analysis, documentation of existing databases, technology developments, and other standardization efforts in the geoscience and computer-science communities. A key aspect of the model is the notion that representation of the conceptual framework (ontology) that underlies geologic map data must be part of the model, because this framework changes with time and understanding, and varies between information providers. The top level of the model distinguishes geologic concepts, geologic representation concepts, and metadata. The geologic representation part of the model provides a framework for representing the ontology that underlies geologic map data through a controlled vocabulary, and for establishing the relationships between this vocabulary and a geologic map visualization or portrayal. Top-level geologic classes in the model are Earth material (substance), geologic unit (parts of the Earth), geologic age, geologic structure, fossil, geologic process, geologic relation, and geologic event.

Defining the Geoscience Community through a Quantitative Perspective

NASA Astrophysics Data System (ADS)

Wilson, C. E.; Keane, C. M.

2015-12-01

The American Geosciences Institute's (AGI) Geoscience Workforce Program collects and analyzes data pertaining to the changes in the supply, demand, and training of the geoscience workforce. These data cover the areas of change in the education of future geoscientists from K-12 through graduate school, the transition of geoscience graduates into early-career geoscientists, the dynamics of the current geoscience workforce, and the future predictions of the changes in the availability of geoscience jobs. The Workforce Program also considers economic changes in the United States and globally that can affect the supply and demand of the geoscience workforce. In order to have an informed discussion defining the modern geoscience community, it is essential to understand the current dynamics within the geoscience community and workforce. This presentation will provide a data-driven outlook of the current status of the geosciences in the workforce and within higher education using data collected by AGI, federal agencies and other stakeholder organizations. The data presented will highlight the various industries, including those industries with non-traditional geoscience jobs, the skills development of geoscience majors, and the application of these skills within the various industries in the workforce. This quantitative overview lays the foundation for further discussions related to tracking and understanding the current geoscience community in the United States, as well as establishes a baseline for global geoscience workforce comparisons in the future.

Aerial Remote Radio Frequency Identification System for Small Vessel Monitoring

DTIC Science & Technology

2009-12-01

Assessment Methods , Ocean Studies Board, Commission on Geosciences, Environment, and Resources, National Research Council. (1998). Improving fish stock... Research Council (NRC). (2006). Review of recreational fisheries survey methods . Washington, DC: The National Academies Press. NOAA Fisheries. (1996...MONITORING AGENCY NAME(S) AND ADDRESS(ES) Acquisition Research Program 10. SPONSORING/MONITORING AGENCY REPORT NUMBER 11. SUPPLEMENTARY NOTES The

Conceptual Learning Outcomes of Virtual Experiential Learning: Results of Google Earth Exploration in Introductory Geoscience Courses

NASA Astrophysics Data System (ADS)

Bitting, Kelsey S.; McCartney, Marsha J.; Denning, Kathy R.; Roberts, Jennifer A.

2018-06-01

Virtual globe programs such as Google Earth replicate real-world experiential learning of spatial and geographic concepts by allowing students to navigate across our planet without ever leaving campus. However, empirical evidence for the learning value of these technological tools and the experience students gain by exploration assignments framed within them remains to be quantified and compared by student demographics. This study examines the impact of a Google Earth-based exploration assignment on conceptual understanding in introductory geoscience courses at a research university in the US Midwest using predominantly traditional college-age students from a range of majors. Using repeated-measures ANOVA and paired-samples t tests, we test the significance of the activity using pretest and posttest scores on a subset of items from the Geoscience Concept Inventory, and the interactive effects of student gender and ethnicity on student score improvement. Analyses show that learning from the Google Earth exploration activity is highly significant overall and for all but one of the concept inventory items. Furthermore, we find no significant interactive effects of class format, student gender, or student ethnicity on the magnitude of the score increases. These results provide strong support for the use of experiential learning in virtual globe environments for students in introductory geoscience and perhaps other disciplines for which direct observation of our planet's surface is conceptually relevant.

InTeGrate's model for developing innovative, adaptable, interdisciplinary curricular materials that reach beyond the geosciences

NASA Astrophysics Data System (ADS)

Egger, A. E.; Baldassari, C.; Bruckner, M. Z.; Iverson, E. A.; Manduca, C. A.; Mcconnell, D. A.; Steer, D. N.

2013-12-01

InTeGrate is NSF's STEP Center in the geosciences. A major goal of the project is to develop curricula that will increase the geoscience literacy of all students such that they are better positioned to make sustainable decisions in their lives and as part of the broader society. This population includes the large majority of students that do not major in the geosciences, those historically under-represented in the geosciences, and future K-12 teachers. To achieve this goal, we established a model for the development of curricular materials that draws on the distributed expertise of the undergraduate teaching community. Our model seeks proposals from across the higher education community for courses and modules that meet InTeGrate's overarching goals. From these proposals, we select teams of 3-5 instructors from three or more different institutions (and institution types) and pair them with assessment and web experts. Their communication and development process is supported by a robust, web-based content management system (CMS). Over two years, this team develops materials that explicitly address a geoscience-related societal challenge, build interdisciplinary problem-solving skills, make use of real geoscience data, and incorporate geoscientific and systems thinking. Materials are reviewed with the InTeGrate design rubric and then tested by the authors in their own courses, where student learning is assessed. Results are reviewed by the authors and our assessment team to guide revisions. Several student audiences are targeted: students in general education and introductory geoscience courses, pre-service K-12 teachers, students in other science and engineering majors, as well as those in the humanities and social sciences. Curriculum development team members from beyond the geosciences are critical to producing materials that can be adopted for all of these audiences, and we have been successful in engaging faculty from biology, economics, engineering, sociology, Spanish, and other disciplines. In its first year, InTeGrate engaged 20 individuals from 17 different institutions on materials development teams. During interviews and responses to open-ended survey questions, first-year team members provided feedback about the challenges and successes of the model. Several described that the materials design rubric was a useful tool in guiding their work and pushed them in directions they may not have otherwise gone. Most responded that working as part of a team with members from different institutions created numerous challenges, but was ultimately beneficial in sharing ideas and resulted in a better product. Other key components to model success are the development of resources by the web experts to support use of the CMS and frequent feedback from the assessment team. All feedback was used to refine the model for the second year, during which 56 additional authors have begun to develop materials. By engaging this broad and diverse community in innovative curriculum development, we anticipate widespread adoption of InTeGrate materials.

Agent Based Modeling Applications for Geosciences

NASA Astrophysics Data System (ADS)

Stein, J. S.

2004-12-01

Agent-based modeling techniques have successfully been applied to systems in which complex behaviors or outcomes arise from varied interactions between individuals in the system. Each individual interacts with its environment, as well as with other individuals, by following a set of relatively simple rules. Traditionally this "bottom-up" modeling approach has been applied to problems in the fields of economics and sociology, but more recently has been introduced to various disciplines in the geosciences. This technique can help explain the origin of complex processes from a relatively simple set of rules, incorporate large and detailed datasets when they exist, and simulate the effects of extreme events on system-wide behavior. Some of the challenges associated with this modeling method include: significant computational requirements in order to keep track of thousands to millions of agents, methods and strategies of model validation are lacking, as is a formal methodology for evaluating model uncertainty. Challenges specific to the geosciences, include how to define agents that control water, contaminant fluxes, climate forcing and other physical processes and how to link these "geo-agents" into larger agent-based simulations that include social systems such as demographics economics and regulations. Effective management of limited natural resources (such as water, hydrocarbons, or land) requires an understanding of what factors influence the demand for these resources on a regional and temporal scale. Agent-based models can be used to simulate this demand across a variety of sectors under a range of conditions and determine effective and robust management policies and monitoring strategies. The recent focus on the role of biological processes in the geosciences is another example of an area that could benefit from agent-based applications. A typical approach to modeling the effect of biological processes in geologic media has been to represent these processes in a thermodynamic framework as a set of reactions that roll-up the integrated effect that diverse biological communities exert on a geological system. This approach may work well to predict the effect of certain biological communities in specific environments in which experimental data is available. However, it does not further our knowledge of how the geobiological system actually functions on a micro scale. Agent-based techniques may provide a framework to explore the fundamental interactions required to explain the system-wide behavior. This presentation will present a survey of several promising applications of agent-based modeling approaches to problems in the geosciences and describe specific contributions to some of the inherent challenges facing this approach.

Quantitative Literacy: Geosciences and Beyond

NASA Astrophysics Data System (ADS)

Richardson, R. M.; McCallum, W. G.

2002-12-01

Quantitative literacy seems like such a natural for the geosciences, right? The field has gone from its origin as a largely descriptive discipline to one where it is hard to imagine failing to bring a full range of mathematical tools to the solution of geological problems. Although there are many definitions of quantitative literacy, we have proposed one that is analogous to the UNESCO definition of conventional literacy: "A quantitatively literate person is one who, with understanding, can both read and represent quantitative information arising in his or her everyday life." Central to this definition is the concept that a curriculum for quantitative literacy must go beyond the basic ability to "read and write" mathematics and develop conceptual understanding. It is also critical that a curriculum for quantitative literacy be engaged with a context, be it everyday life, humanities, geoscience or other sciences, business, engineering, or technology. Thus, our definition works both within and outside the sciences. What role do geoscience faculty have in helping students become quantitatively literate? Is it our role, or that of the mathematicians? How does quantitative literacy vary between different scientific and engineering fields? Or between science and nonscience fields? We will argue that successful quantitative literacy curricula must be an across-the-curriculum responsibility. We will share examples of how quantitative literacy can be developed within a geoscience curriculum, beginning with introductory classes for nonmajors (using the Mauna Loa CO2 data set) through graduate courses in inverse theory (using singular value decomposition). We will highlight six approaches to across-the curriculum efforts from national models: collaboration between mathematics and other faculty; gateway testing; intensive instructional support; workshops for nonmathematics faculty; quantitative reasoning requirement; and individual initiative by nonmathematics faculty.

Study on various elements of the geosciences with respect to space technology

NASA Technical Reports Server (NTRS)

Head, J. W., III

1981-01-01

The utility of data acquired in space for both basic and applied studies of the geology of the Earth was evaluated. Focus was placed upon the gaps in the current ability to make effective use of remote sensing technology within the Earth sciences. A long range plan is presented for future research that involves an appropriate balance between the development and application of space techniques.

Enabling Data-as- a-Service (DaaS) - Biggest Challenge of Geoscience Australia

NASA Astrophysics Data System (ADS)

Bastrakova, I.; Kemp, C.; Car, N. J.

2016-12-01

Geoscience Australia (GA) is recognised and respected as the national repository and steward of multiple national significance data collections that provides geoscience information, services and capability to the Australian Government, industry and stakeholders. Provision of Data-as-a-Service is both GA's key responsibility and core business. Through the Science First Transformation Program GA is undergoing a significant rethinking of its data architecture, curation and access to support the Digital Science capability for which DaaS forms both a dependency and underpins its implementation. DaaS, being a service, means we can deliver its outputs in multiple ways thus providing users with data on demand in ready-for-consumption forms. We can then to reuse prebuilt data constructions to allow self-serviced integration of data underpinned by dynamic query tools. In GA's context examples of DaaS are the Australian Geoscience Data Cube, the Foundation Spatial Data Framework and data served through several Virtual Laboratories. We have implemented a three-layered architecture for DaaS in order to store and manage the data while honouring the semantics of Scientific Data Models defined by subject matter experts and GA's Enterprise Data Architecture as well as retain that delivery flexibility. The foundation layer of DaaS is Canonical Datasets, which are optimised for a long-term data stewardship and curation. Data is well structured, standardised, described and audited. All data creation and editing happen within this layer. The middle Data Transformation layer assists with transformation of data from Canonical Datasets to data integration layer. It provides mechanisms for multi-format and multi-technology data transformation. The top Data Integration layer is optimised for data access. Data can be easily reused and repurposed; data formats made available are optimised for scientific computing and adjusted for access by multiple applications, tools and libraries. Moving to DaaS enables GA to increase data alertness, generate new capabilities and be prepared for emerging technological challengers.

Ocean FEST (Families Exploring Science Together)

NASA Astrophysics Data System (ADS)

Bruno, B. C.; Wiener, C. S.

2009-12-01

Ocean FEST (Families Exploring Science Together) exposes families to cutting-edge ocean science research and technology in a fun, engaging way. Research has shown that family involvement in science education adds significant value to the experience. Our overarching goal is to attract underrepresented students (including Native Hawaiians, Pacific Islanders and girls) to geoscience careers. A second goal is to communicate to diverse audiences that geoscience is directly relevant and applicable to their lives, and critical in solving challenges related to global climate change. Ocean FEST engages elementary school students, parents, teachers, and administrators in family science nights based on a proven model developed by Art and Rene Kimura of the Hawaii Space Grant Consortium. Our content focuses on the role of the oceans in climate change, and is based on the transformative research of the NSF Center for Microbial Oceanography: Research and Education (C-MORE) and the Hawaii Institute of Marine Biology (HIMB). Through Ocean FEST, underrepresented students and their parents and teachers learn about new knowledge being generated at Hawaii’s world-renowned ocean research institutes. In the process, they learn about fundamental geoscience concepts and career opportunities. This project is aligned with C-MORE’s goal of increasing the number of underrepresented students pursuing careers in the ocean and earth sciences, and related disciplines. Following a successful round of pilot events at elementary schools on Oahu, funding was obtained through NSF Opportunities for Enhancing Diversity in the Geosciences to implement a three-year program at minority-serving elementary schools in Hawaii. Deliverables include 20 Ocean FEST events per year (each preceded by teacher professional development training), a standards-based program that will be disseminated locally and nationally, three workshops to train educators in program delivery, and an Ocean FEST science kit. In addition, we are currently conducting a series of pilot events at the middle school level at underserved schools at neighbor islands, funded through the Hawaii Innovation Initiative (Act 111). Themes addressed include community outreach, capacity building, teacher preparation, and use of technology.

Terrestrial Laser Scanning and Structure from Motion teaching resources for undergraduate field education courses

NASA Astrophysics Data System (ADS)

Pratt-Sitaula, B. A.; Shervais, K.; Crosby, C. J.; Douglas, B. J.; Niemi, N. A.; Wang, G.; Charlevoix, D. J.

2015-12-01

Fieldwork is an integral part of the geosciences and there is a longstanding tradition of teaching field methods as part of the undergraduate curriculum. As new technology changes the ways in which we scientifically examine the Earth, and as workforce development demands evolve, there is growing interest in introducing these new technologies into field education courses. In collaboration with field education instructors, UNAVCO, the National Science Foundation's geodetic facility, has developed a module of teaching resources to integrate terrestrial lidar scanning into field courses. An NSF facility is well positioned to develop scalable resources that can then be distributed or adapted for broader implementation. The modules can also be accomplished using Structure from Motion methods in place of lidar scanning. Modules goals are for students to be able to: (A) design and conduct a complex TLS survey to address a geologic research question and (B) articulate the societal impetus for answering these research questions and identify why TLS is the appropriate method in some circumstances. The module is comprised of five units: (1) Introduction to survey design, (2) Stratigraphic section analysis, (3) Fault scarp analysis, (4) Geomorphic change detection, (5) Student-led survey design summative assessment. The modules, apart from the Introduction, are independent, thus select modules can be employed in a given field setting. Prototype module materials were developed from the last five years of UNAVCO support of undergraduate field courses. The current versions of the modules were tested in summer 2015 at the Indiana University and University of Michigan field camps. Results show that the majority of students are able to achieve the intended learning goals. Module materials are available on the UNAVCO Education and Community Engagement website.

Where in the World Will We Find Our Future Geoscientists?: One Employer's Perspective

NASA Astrophysics Data System (ADS)

Loudin, M. G.

2004-12-01

The challenges we face in finding and developing new energy resources to satisfy increasing global demand are driving us to update the attributes we seek in our entry-level Geoscientists. These attributes include a foundation of necessary technical talents and skills, as well as experimental approaches and geographic considerations. The resulting changes to our entry-level "demand profile," when convolved with the current global academic Geoscience landscape, present opportunities for development of alternative paradigms in how new Geoscientists are developed. While we have always stressed the need for strong, "classical" Earth Science fundamentals in our campus hires, both exploration and production business challenges point the way to an even greater emphasis on quantitative skills. For instance, accurately imaging deep structures overlain by highly complex salt strata in the Gulf of Mexico will require people who can balance an understanding of sedimentological and deformational processes with and understanding of the physics of wave propagation. Our experience has been that there are relatively few academic programs that stress both classical Geology and high-end quantitative skills for their graduates. Since we are in the business of remotely predicting subsurface conditions better than we ever have before, how well students are prepared in their approach to experimentation is ever more important to us. How well do students understand the systemic context of their work? Do they employ an approach characterized by multiple working hypotheses? How well are such hypotheses constrained by existing knowledge from other workers? Are their experiments well-designed and controlled such that some hypotheses can be unambiguously ruled out? Geographically, the locations of our resources and production will continue to shift away from areas like the US, Canada, Europe, and Australia. Since our research facilities and various centers of expertise reside in the US, we will continue to hire a high percentage of our Geoscientists in the US for employment here. However, decreasing internal demand for Geoscientists from Canada, Australia, and Europe will mean that our focus in these areas will largely shift to filling positions in our US research center and centers of expertise for which qualified US graduates cannot be found. As the proportion of our resources and production shifts into other areas, demand for highly qualified Geoscience graduates from these areas increases. Often, Geoscience departments in these areas are in an early stage of development. As many mature Geoscience departments face profound challenges from decreasing enrollments and funding, there is potential for "win-win" situations in which such departments work with governments that are interested in accelerating development of their academic institutions.

The European Network of Analytical and Experimental Laboratories for Geosciences

NASA Astrophysics Data System (ADS)

Freda, Carmela; Funiciello, Francesca; Meredith, Phil; Sagnotti, Leonardo; Scarlato, Piergiorgio; Troll, Valentin R.; Willingshofer, Ernst

2013-04-01

Integrating Earth Sciences infrastructures in Europe is the mission of the European Plate Observing System (EPOS).The integration of European analytical, experimental, and analogue laboratories plays a key role in this context and is the task of the EPOS Working Group 6 (WG6). Despite the presence in Europe of high performance infrastructures dedicated to geosciences, there is still limited collaboration in sharing facilities and best practices. The EPOS WG6 aims to overcome this limitation by pushing towards national and trans-national coordination, efficient use of current laboratory infrastructures, and future aggregation of facilities not yet included. This will be attained through the creation of common access and interoperability policies to foster and simplify personnel mobility. The EPOS ambition is to orchestrate European laboratory infrastructures with diverse, complementary tasks and competences into a single, but geographically distributed, infrastructure for rock physics, palaeomagnetism, analytical and experimental petrology and volcanology, and tectonic modeling. The WG6 is presently organizing its thematic core services within the EPOS distributed research infrastructure with the goal of joining the other EPOS communities (geologists, seismologists, volcanologists, etc...) and stakeholders (engineers, risk managers and other geosciences investigators) to: 1) develop tools and services to enhance visitor programs that will mutually benefit visitors and hosts (transnational access); 2) improve support and training activities to make facilities equally accessible to students, young researchers, and experienced users (training and dissemination); 3) collaborate in sharing technological and scientific know-how (transfer of knowledge); 4) optimize interoperability of distributed instrumentation by standardizing data collection, archive, and quality control standards (data preservation and interoperability); 5) implement a unified e-Infrastructure for data analysis, numerical modelling, and joint development and standardization of numerical tools (e-science implementation); 6) collect and store data in a flexible inventory database accessible within and beyond the Earth Sciences community(open access and outreach); 7) connect to environmental and hazard protection agencies, stakeholders, and public to raise consciousness of geo-hazards and geo-resources (innovation for society). We will inform scientists and industrial stakeholders on the most recent WG6 achievements in EPOS and we will show how our community is proceeding to design the thematic core services.

Teen Science Cafés: A Model for Addressing Broader Impacts, Diversity, and Recruitment

NASA Astrophysics Data System (ADS)

Hall, M.; Mayhew, M. A.

2017-12-01

Teen Science Café programs (TeenScienceCafe.org) are a free and fun way for teens to explore science and technology affecting their lives. Through lively presentations, conversation, and activities to explore a topic deeply, Café programs open doors for teens to learn from experts about exciting and rewarding STEM career pathways. The programs are local and led by teens with the help of an adult mentor. The Teen Science Café Network (teensciencecafe.org) provides mentoring and resources, including small grants, to help organizations get started with and then maintain successful "teen café" programs. Through membership in the Network, more than 80 Teen Science Cafés have sprung up across the country, from rural towns to major cities. They serve a critical need for teens - meeting and engaging with STEM professionals, learning about their career paths, and seeing their passion for the work they do. Teen Science Café programs can offer geoscience departments a substantive, yet low cost, way to meet the challenges many of them face: finding ways to increase enrollment, helping faculty satisfy the broader impacts requirements of funding agencies, connecting with the surrounding communities, and providing opportunities for faculty and graduate students to learn how to communicate their science effectively to the public audience. The typical experience of scientists who have presented in teen cafés throughout the Network is that the communication skills learned spill over into their courses, proposals, and presentations to administrators and program officers. A department might partner with one or more organizations in their surrounding communities—libraries, for example—and engage its faculty and its graduate students—and even its undergraduates—in providing geoscience programming across multiple disciplines to local teens. Besides the internal benefits to the department's personnel and the value of establishing connections with community organizations, the impact of such engagement might well be attracting students to the department. We seek geoscience departments that are interested in this concept and willing to join the Teen Science Café Network (TeenScienceCafe.org) and participate in a study of how Teen Science Cafés may impact undergraduate recruitment to their departments.

Community Based Informatics: Geographical Information Systems, Remote Sensing and Ontology collaboration - A technical hands-on approach

NASA Astrophysics Data System (ADS)

Branch, B. D.; Raskin, R. G.; Rock, B.; Gagnon, M.; Lecompte, M. A.; Hayden, L. B.

2009-12-01

With the nation challenged to comply with Executive Order 12906 and its needs to augment the Science, Technology, Engineering and Mathematics (STEM) pipeline, applied focus on geosciences pipelines issue may be at risk. The Geosciences pipeline may require intentional K-12 standard course of study consideration in the form of project based, science based and evidenced based learning. Thus, the K-12 to geosciences to informatics pipeline may benefit from an earth science experience that utilizes a community based “learning by doing” approach. Terms such as Community GIS, Community Remotes Sensing, and Community Based Ontology development are termed Community Informatics. Here, approaches of interdisciplinary work to promote and earth science literacy are affordable, consisting of low cost equipment that renders GIS/remote sensing data processing skills necessary in the workforce. Hence, informal community ontology development may evolve or mature from a local community towards formal scientific community collaboration. Such consideration may become a means to engage educational policy towards earth science paradigms and needs, specifically linking synergy among Math, Computer Science, and Earth Science disciplines.

How FOSTER supports training Open Science in the GeoSciences

NASA Astrophysics Data System (ADS)

Orth, Astrid

2016-04-01

FOSTER (1) is about promoting and facilitating the adoption of Open Science by the European research community, and fostering compliance with the open access policies set out in Horizon 2020 (H2020). FOSTER aims to reach out and provide training to the wide range of disciplines and countries involved in the European Research Area (ERA) by offering and supporting face-to-face as well as distance training. Different stakeholders, mainly young researchers, are trained to integrate Open Science in their daily workflow, supporting researchers to optimise their research visibility and impact. Strengthening the institutional training capacity is achieved through a train-the-trainers approach. The two-and-half-year project started in February 2014 with identifying, enriching and providing training content on all relevant topics in the area of Open Science. One of the main elements was to support two rounds of trainings, which were conducted during 2014 and 2015, organizing more than 100 training events with around 3000 participants. The presentation will explain the project objectives and results and will look into best practice training examples, among them successful training series in the GeoSciences. The FOSTER portal that now holds a collection of training resources (e.g. slides and PDFs, schedules and design of training events dedicated to different audiences, video captures of complete events) is presented. It provides easy ways to identify learning materials and to create own e-learning courses based on the materials and examples. (1) FOSTER is funded through the European Union's Seventh Framework Programme for research, technological development and demonstration under grant agreement no 612425. http://fosteropenscience.eu

Providing Interactive Access to Cave Geology for All Students, Regardless of Physical Ability

NASA Astrophysics Data System (ADS)

Atchison, C. `; Stredney, D.; Hittle, B.; Irving, K.; Toomey, R. S., III; Lemon, N. N.; Price, A.; Kerwin, T.

2013-12-01

Based on an identified need to accommodate students with mobility impairments in field-based instructional experiences, this presentation will discuss current efforts to promote participation, broaden diversity, and impart a historical perspective in the geosciences through the use of an interactive virtual environment. Developed through the integration of emerging simulation technologies, this prototypical virtual environment is created from LIDAR data of the Historic Tour route of Mammoth Cave National Park. The educational objectives of the simulation focus on four primary locations within the tour route that provide evidence of the hydrologic impact on the cave and karst formation. The overall objective is to provide a rich experience of a geological field-based learning for all students, regardless of their physical abilities. Employing a virtual environment that interchangeably uses two and three-dimensional representation of geoscience content, this synthetic field-based cave and karst module will provide an opportunity to assess the effectiveness in engaging the student community, and its efficacy in the curriculum when used as an alternative representation of a traditional field experience. The expected outcome is that based on the level of interactivity, the simulated environment will provide adequate pedagogical representation for content transfer without the need for physical experience in the uncontrolled field environment. Additionally, creating such an environment will impact all able-bodied students by providing supplemental resources that can both precede a traditional field experience and allow for students to re-examine a field site long after a the field experience, in both current formal and informal educational settings.

Earth Science Week 2009, "Understanding Climate", Highlights and News Clippings

DOE Office of Scientific and Technical Information (OSTI.GOV)

Robeck, Edward C.

2010-01-05

The American Geological Institute (AGI) proposes to expand its influential Earth Science Week Program in 2009, with the support of the U.S. Department of Energy, to disseminate DOE's key messages, information, and resources on climate education and to include new program components. These components, ranging from online resources to live events and professional networks, would significantly increase the reach and impact of AGI's already successful geoscience education and public awareness effort in the United States and abroad in 2009, when the campaign's theme will be "Understanding Climate."

A Modern Explorer's Journey - using events for innovative multipurpose educational outreach

NASA Astrophysics Data System (ADS)

Lilja Bye, Bente

2014-05-01

Earth observations are important across the specter of geo-sciences. The Group on Earth Observations (GEO) is coordinating efforts to build a Global Earth Observation System of Systems, or GEOSS. The lack of dedicated funding to support specific Science &Technology activities in support of GEOSS is one of the most important obstacles to engaging the Science &Technology communities in its implementation. Finding resources to outreach and capacity building is likewise a challenge. The continuation of GEO and GEOSS rely on political support which again is influenced by public opinions. The GEO Ministerial Summit in 2014 was an event that both needed visibility and represented an opportunity to mobilize the GEO community in producing outreach and educational material. Through the combined resources from two of GEO tasks in the GEO work plan, a multipurpose educational outreach project was planned and executed. This project addressed the following issues: How can the GEO community mobilize resources for its work plan projects in the Societal Benefit Area Water? How can we produce more educational and capacity building material? How can the GEO community support the GEO secretariat related to public relations (material and otherwise) Based on activities described in the GEO work plan, a showcase video and online campaign consisting on a series of webinars were developed and produced. The video and webinars were linked through a common reference: the water cycle. Various aspects of the water cycle ranging from general to more technical and scientific education were covered in the webinars, while the video called A Modern Explorer's Journey focused on story telling with a more emotional appeal. The video was presented to the Ministers at the GEO Ministerial Summit and distributed widely to the GEO community and through social media and articles (as embedded YouTube and more). A discussion of challenges and successes of this event-based educational outreach project will be presented. Continued use of new outreach tools such as web technology and social innovations for more efficient use of limited resources will remain an issue for the scientific community. Lessons learned need to be provided continuously and this project add to this material.

Telescopic Topics: The Impact of Student-Created Podcasts in a Large, General Education Course

NASA Astrophysics Data System (ADS)

Kraal, E. R.

2014-12-01

Large, general education courses are important to the geoscience community. These courses serve as valuable recruiting tools for future geoscience majors because over 55% of geoscience students select their major in the first two years of college (Wilson, 2013). These courses can have many challenges such as large class sizes, limited (or no) laboratory time and facilities, little financial resource support, non-permanent faculty, and a variety of student abilities and needs. High impact practices, such as writing courses, student research, and community service can be difficult to integrate into large, non-major courses. Student-produced audio (e. g. podcasts) provide one approach to providing high impact practices within these courses. Other researchers have found student produced audio to be effective at transmitting content, integrating place based experiences, and building community connections within the students. Here I present the implementation of student-created audio within a large (100+), general education course (AST 30 - Mission to the Planets) over the last 4 years called 'Telescopic Topics.' Activities scaffold the students through the semester where they select a topic on planetary science, work with the science reference librarian, visit the writing center, and record their podcast at campus student radio station. The top podcasts are then aired on the campus radio station during the news broadcasts through a rotating series. Surveys of student experiences find that student find the activity valuable and engaging. Students reported feeling less intimidated by the science content and more connected to the subject matter. In addition, it provides many of them with their first introduction to and use of the university library and associated campus resources.

A Collaborative Effort to Increase Enrollment and Retention in Geoscience Majors in North Carolina

NASA Astrophysics Data System (ADS)

Thomas, C. J.; Fountain, J. C.; Bartek, C. S.; Tang, G.

2004-12-01

Under an NSF Opportunities for Enhancement of Diversity in Geosciences grant, the Department of Marine, Earth and Atmospheric Sciences at North Carolina State University partnered with NC A&T University, a HBCU, to implement a multi-faceted effort to increase enrollment and retention in geoscience majors, with particular emphasis on under represented groups. New student recruitment is facilitated by a trained graduate student who visits high schools and presents a multi-media presentation on research at NCSU and career opportunities in the geosciences. Interested high school students are then invited to participate in a hands-on, summer science camp. Community college students are recruited through a new introductory geology course developed for and offered at Robeson Community College (77% of students from under represented groups). NC A&T has developed a track in their physics curriculum to prepare students for a geophysics career. The track includes a planned semester in residence at NCSU. Students who choose to enroll at NCSU, register for an introductory course developed as part of our NSF STEP grant, Environmental Issues in Water Resources, during which geoscience careers are highlighted and in-class research focuses on a local watershed. The emphasis on undergraduate research continues with Environmental Geology, an upper division course in which the entire class studies water and sediment contamination on local watersheds. All courses developed build upon our physics department's successful model of integrating lectures and laboratories and engaging first-year students in group-oriented, undergraduate research (http://www.physics.ncsu.edu/physics_ed/). Following the group research courses, advanced undergraduate students are placed in traditional research labs with faculty mentors while participating in a career development seminar in which research methods, proposal writing and presentation skills are introduced. Tutoring and mentoring programs provide support for all majors. Formative assessment is ongoing, including pre and post surveys to assess course effectiveness and changes in attitudes toward science.

Information Superiority generated through proper application of Geoinformatics

NASA Astrophysics Data System (ADS)

Teichmann, F.

2012-04-01

Information Superiority generated through proper application of Geoinformatics Information management and especially geoscience information delivery is a very delicate task. If it is carried out successfully, geoscientific data will provide the main foundation of Information Superiority. However, improper implementation of geodata generation, assimilation, distribution or storage will not only waste valuable resources like manpower or money, but could also give rise to crucial deficiency in knowledge and might lead to potentially extremely harmful disasters or wrong decisions. Comprehensive Approach, Effect Based Operations and Network Enabled Capabilities are the current buzz terms in the security regime. However, they also apply to various interdisciplinary tasks like catastrophe relief missions, civil task operations or even in day to day business operations where geo-science data is used. Based on experience in the application of geoscience data for defence applications the following procedure or tool box for generating geodata should lead to the desired information superiority: 1. Understand and analyse the mission, the task and the environment for which the geodata is needed 2. Carry out a Information Exchange Requirement between the user or customer and the geodata provider 3. Implementation of current interoperability standards and a coherent metadata structure 4. Execute innovative data generation, data provision, data assimilation and data storage 5. Apply a cost-effective and reasonable data life cycle 6. Implement IT security by focusing of the three pillar concepts Integrity, Availability and Confidentiality of the critical data 7. Draft and execute a service level agreement or a memorandum of understanding between the involved parties 8. Execute a Continuous Improvement Cycle These ideas from the IT world should be transferred into the geoscience community and applied in a wide set of scenarios. A standardized approach of how to generate, provide, handle, distribute and store geodata will can reduce costs, strengthen the ties between service costumer and geodata provider and improve the contribution geoscience can make for achieving information superiority for decision makers.

The Global ASTER Geoscience and Mineralogical Maps

NASA Astrophysics Data System (ADS)

Abrams, M.

2017-12-01

In 2012, Australia's Commonwealth Scientific and Industrial Research Organization (CSIRO) released 17 Geoscience mineral maps for the continent of Australia We are producing the CSIRO Geoscience data products for the entire land surface of the Earth. These maps are created from Advanced Spacecraft Thermal Emission and Reflection Radiometer (ASTER) data, acquired between 2000 and 2008. ASTER, onboard the United States' Terra satellite, is part of NASA's Earth Observing System. This multispectral satellite system has 14 spectral bands spanning: the visible and near-infrared (VNIR) @ 15 m pixel resolution; shortwave-infrared (SWIR) @ 30 m pixel resolution; and thermal infrared (TIR) @ 90 m pixel resolution. In a polar-orbit, ASTER acquires a 60 km swath of data.The CSIRO maps are the first continental-scale mineral maps generated from an imaging satellite designed to measure clays, quartz and other minerals. Besides their obvious use in resource exploration, the data have applicability to climatological studies. Over Australia, these satellite mineral maps improved our understanding of weathering, erosional and depositional processes in the context of changing weather, climate and tectonics. The clay composition map showed how kaolinite has developed over tectonically stable continental crust in response to deep weathering. The same clay composition map, in combination with one sensitive to water content, enabled the discrimination of illite from montmorillonite clays that typically develop in large depositional environments over thin (sinking) continental crust. This product was also used to measure temporal gains/losses of surface clay caused by periodic wind erosion (dust) and rainfall inundation (flood) events. The two-year project is undertaken by JPL with collaboration from CSIRO. JPL has in-house the entire ASTER global archive of Level 1B image data—more than 1,500,000 scenes. This cloud-screened and vegetation-masked data set will be the basis for creation of the suite of global Geoscience products using all of ASTER's 14 VNIR-SWIR-TIR spectral bands resampled to 100 m pixel resolution. We plan a staged release of the geoscience products through NASA's LPDAAC.

Transitioning from Faculty-Led Lecture to Student-Centered Field Learning Facilitated by Near-Peer Mentors: Preliminary Findings from the GeoFORCE/ STEMFORCE Program.

NASA Astrophysics Data System (ADS)

Berry, M.; Wright, V. D.; Ellins, K. K.; Browder, M. G. J.; Castillo, R.; Kotowski, A. J.; Libarkin, J. C.; Lu, J.; Maredia, N.; Butler, N.

2017-12-01

GeoFORCE Texas, a geology-based outreach program in the Jackson School of Geosciences, offers weeklong summer geology field based courses to secondary students from minority-serving high schools in Texas and the Bahamas. Students transitioning from eighth to ninth grade are recruited into the program and ideally remain in GeoFORCE for four years. The program aims to empower underrepresented students by exposing them to experiences intended to inspire them to pursue geoscience or other STEM careers. Since the program's inception in 2005, GeoFORCE Texas has relied on a mix of classroom lectures delivered by a geoscience faculty member and time in the field. Early research findings from a National Science Foundation-sponsored GeoPaths-IMPACT project are influencing the evolution of field instruction away from the faculty-led lecture model to student-centered learning that may improve students' grasp of key geological concepts. The eleventh and twelfth grade programs are shifting towards this strategy. Each trip is facilitated by a seven-person team comprised of a geoscience graduate student, master teachers, four undergraduate geology students, and preservice teachers. Members of the instructional team reflected the racial, ethnic, and cultural diversity that the geoscience strives to achieve; all are excellent role models for GeoFORCE students. The outcome of the most recent Central Texas twelfth grade trip, which used a student-centered, project-based approach, was especially noteworthy. Each group was given a topic to apply to what they saw in the field, such as fluvial systems, cultural significance, or geohazards, etc., and present in any manner in front of peers and a panel of geoscience experts. Students used the latest presentation technology available to them (e.g. Prezi, iMovies) and sketches and site notes from field stops. The final presentations were clear, informative, and entertaining. It can be concluded that the students were more engaged with the peer-teaching method than in prior years when they read the field manuals. Knowing they had to produce a presentation gave them motivation to focus and absorb information. They successfully took their new geological knowledge and applied existing skillsets that will be useful for college and, hopefully, a future career in geosciences or STEM field.

Geoscience and a Lunar Base: A Comprehensive Plan for Lunar Exploration

NASA Technical Reports Server (NTRS)

Taylor, G. Jeffrey (Editor); Spudis, Paul D. (Editor)

1990-01-01

This document represents the proceedings of the Workshop on Geoscience from a Lunar Base. It describes a comprehensive plan for the geologic exploration of the Moon. The document begins by explaining the scientific importance of studying the Moon and outlines the many unsolved problems in lunar science. Subsequent chapters detail different, complementary approaches to geologic studies: global surveys, including orbiting spacecraft such as Lunar Observer and installation of a global geophysical network; reconnaissance sample return mission, by either automated rovers or landers, or by piloted forays; detailed field studies, which involve astronauts and teleoperated robotic field geologists. The document then develops a flexible scenario for exploration and sketches the technological developments needed to carry out the exploration scenario.

Development of a geoscience curriculum in a small liberal arts college

NASA Astrophysics Data System (ADS)

Toteva, T.

2007-12-01

Geoscience programs with emphasis on geophysics are traditionally offered in research type of universities. Most small liberal arts colleges do not have the resources to offer geophysics education. Randolph College (Lynchburg, VA) is becoming one of the few small schools that provide a unique opportunity for undergraduate students to acquire basic knowledge and skills in geoscience methods, in particular in geophysics. One faculty member was hired a year ago and charged to offer a number of classes and labs in geoscience. As a result of that today the college has a geophysics lab with a 250 MHz GPR antenna, a 12 channel Geometrics Geode, three sets of geophones, and sieve equipment for geotechnical work. The above equipment was acquired with funds from the college and outside sponsors. In addition, collaboration with Virginia Tech led to the installation of a new seismological station, with a broad band seismograph, on college land. This alone triggered incredible interest in earthquake seismology, not only from students but from the campus community as well. All the equipment is used both for classes and undergraduate research. It has a significant contribution to the rapid increase in interest in the Environmental Studies and Physics programs in the school. It allows the offering of new field based classes. Such classes are always of great interest to students because they provide hands-on experience. As a result of offering these new classes, two new B.S. programs were added to the curriculum - B.S. in Environmental Science and B.S. in Physics.

Green at Fifteen? How 15-Year-Olds Perform in Environmental Science and Geoscience in PISA 2006

ERIC Educational Resources Information Center

OECD Publishing (NJ3), 2009

2009-01-01

Never before have the stakes been so high for the role of science education in shaping how people interact with the environment. Human activities responsible for the production of greenhouse gases, the accumulation of waste, the fragmentation or destruction of ecosystems and the depletion of resources are having a substantial impact on the…

Contracts for field projects and supporting research on enhanced oil recovery. Progress review No. 82, quarterly report, January--March 1995

DOE Office of Scientific and Technical Information (OSTI.GOV)

NONE

This document consists of a list of projects supporting work on oil recovery programs. A publications list and index of companies and institutions is provided. The remaining portion of the document provides brief descriptions on projects in chemical flooding, gas displacement, thermal recovery, geoscience, resource assessment, and reservoir class field demonstrations.

Overcoming Assessment Problems in Google Earth-Based Assignments

ERIC Educational Resources Information Center

Johnson, Nicholas D.; Lang, Nicholas P.; Zophy, Kelley T.

2011-01-01

Educational technologies such as Google Earth have the potential to increase student learning and participation in geoscience classrooms. However, little has been written about tying the use of such software with effective assessment. To maximize Google Earth's learning potential for students, educators need to craft appropriate, research-based…

Using Remote Sensing and Geospatial Technology for Climate Change Education

ERIC Educational Resources Information Center

Cox, Helen; Kelly, Kimberle; Yetter, Laura

2014-01-01

This curriculum and instruction paper describes initial implementation and evaluation of remote-sensing exercises designed to promote post-secondary climate literacy in the geosciences. Tutorials developed by the first author engaged students in the analysis of climate change data obtained from NASA satellite missions, including the LANDSAT,…

An Integrated Field-Based Approach to Building Teachers' Geoscience Skills

ERIC Educational Resources Information Center

Almquist, Heather; Stanley, George; Blank, Lisa; Hendrix, Marc; Rosenblatt, Megan; Hanfling, Seymour; Crews, Jeffrey

2011-01-01

The Paleo Exploration Project was a professional development program for K-12 teachers from rural eastern Montana. The curriculum was designed to incorporate geospatial technologies, including Global Positioning Systems (GPS), Geographic Information Systems (GIS), and total station laser surveying, with authentic field experiences in geology and…

GETIT--Geoscience Education through Interactive Technology[TM]. [CD-ROM].

ERIC Educational Resources Information Center

2000

This CD-ROM uses catastrophic events to teach the fundamentals of the earth's dynamism. Topics discussed include earthquakes, volcanoes, hurricanes, plate tectonics, and many subjects that have to do with energy transfer. It contains 63 interactive, inquiry-based activities that closely simulate real life scientific practice. Students work with…

Shale Gas Information Platform SHIP: the scientific perspective in all that hype

NASA Astrophysics Data System (ADS)

Hübner, A.; Horsfield, B.; Kapp, I.

2012-04-01

With the Shale Gas Information Platform SHIP, the GFZ German Research Centre for Geosciences engages in the public discussion of technical and environmental issues related to shale gas exploration and production. Unconventional fossil fuels, already on stream in the USA, and now under rapid development globally, have brought about a fundamental change in energy resource distribution and energy politics. Among these resources, shale gas is currently most discussed, with the public perspective focusing on putative environmental risk rather than on potential benefits. As far as Europe's own shale gas resources are concerned, scientific and technological innovations will play key roles in defining the dimension of future shale gas production, but it is especially the public's perception and level of acceptance that will make or break shale gas in the near-term. However, opinions on environmental risks diverge strongly: risks are minor and controllable according to industry, while environmental groups often claim the opposite. The Shale Gas Information Platform SHIP brings the perspective of science to the discussion on technical and environmental issues related to shale gas exploration and production. SHIP will not only showcase but discuss what is known and what is not yet know about environmental challenges and potential risks. SHIP features current scientific results and best practice approaches and builds on a network of international experts. The project is interactive and aims to spark discussion among all stakeholders. The Shale Gas Information Platform SHIP covers basic information and news on shale gas, but at the heart of SHIP is the Knowledge Base, a collection of scientific reviews from international experts. The articles give an overview on the current state of knowledge on a certain topic including knowledge gaps, and put this into context of past experiences, current best practices, and opinions expressed by different stakeholders. The articles are open to public comments via the SHIP website, and will be reviewed every three month by the author(s). After approx. one year lifetime, the articles are compiled and published as an E-book by GFZ German Research Centre for Geosciences (Library and Information Centre LIS of the GFZ). A DOI (Document Object Identifier) will be issued for every article (=book chapter). As the whole SHIP website, the E-book will be licensed with a Creative Commons CC-BY-NC-license, in order to promote maximum visibility and distribution in the web.

Centrality-based Selection of Semantic Resources for Geosciences

NASA Astrophysics Data System (ADS)

Cerba, Otakar; Jedlicka, Karel

2017-04-01

Semantical questions intervene almost in all disciplines dealing with geographic data and information, because relevant semantics is crucial for any way of communication and interaction among humans as well as among machines. But the existence of such a large number of different semantic resources (such as various thesauri, controlled vocabularies, knowledge bases or ontologies) makes the process of semantics implementation much more difficult and complicates the use of the advantages of semantics. This is because in many cases users are not able to find the most suitable resource for their purposes. The research presented in this paper introduces a methodology consisting of an analysis of identical relations in Linked Data space, which covers a majority of semantic resources, to find a suitable resource of semantic information. Identical links interconnect representations of an object or a concept in various semantic resources. Therefore this type of relations is considered to be crucial from the view of Linked Data, because these links provide new additional information, including various views on one concept based on different cultural or regional aspects (so-called social role of Linked Data). For these reasons it is possible to declare that one reasonable criterion for feasible semantic resources for almost all domains, including geosciences, is their position in a network of interconnected semantic resources and level of linking to other knowledge bases and similar products. The presented methodology is based on searching of mutual connections between various instances of one concept using "follow your nose" approach. The extracted data on interconnections between semantic resources are arranged to directed graphs and processed by various metrics patterned on centrality computing (degree, closeness or betweenness centrality). Semantic resources recommended by the research could be used for providing semantically described keywords for metadata records or as names of items in data models. Such an approach enables much more efficient data harmonization, integration, sharing and exploitation. * * * * This publication was supported by the project LO1506 of the Czech Ministry of Education, Youth and Sports. This publication was supported by project Data-Driven Bioeconomy (DataBio) from the ICT-15-2016-2017, Big Data PPP call.

GeoMapApp Learning Activities: Enabling the democratisation of geoscience learning

NASA Astrophysics Data System (ADS)

Goodwillie, A. M.; Kluge, S.

2011-12-01

GeoMapApp Learning Activities (http://serc.carleton.edu/geomapapp) are step-by-step guided inquiry geoscience education activities that enable students to dictate the pace of learning. They can be used in the classroom or out of class, and their guided nature means that the requirement for teacher intervention is minimised which allows students to spend increased time analysing and understanding a broad range of geoscience data, content and concepts. Based upon GeoMapApp (http://www.geomapapp.org), a free, easy-to-use map-based data exploration and visualisation tool, each activity furnishes the educator with an efficient package of downloadable documents. This includes step-by-step student instructions and answer sheet; a teacher's edition annotated worksheet containing teaching tips, additional content and suggestions for further work; quizzes for use before and after the activity to assess learning; and a multimedia tutorial. The activities can be used by anyone at any time in any place with an internet connection. In essence, GeoMapApp Learning Activities provide students with cutting-edge technology, research-quality geoscience data sets, and inquiry-based learning in a virtual lab-like environment. Examples of activities so far created are student calculation and analysis of the rate of seafloor spreading, and present-day evidence on the seafloor for huge ancient landslides around the Hawaiian islands. The activities are designed primarily for students at the community college, high school and introductory undergraduate levels, exposing students to content and concepts typically found in those settings.

A synergistic effort among geoscience, physics, computer science and mathematics at Hunter College of CUNY as a Catalyst for educating Earth scientists.

NASA Astrophysics Data System (ADS)

Salmun, H.; Buonaiuto, F. S.

2016-12-01

The Catalyst Scholarship Program at Hunter College of The City University of New York (CUNY) was established with a four-year award from the National Science Foundation (NSF) to fund scholarships for academically talented but financially disadvantaged students majoring in four disciplines of science, technology, engineering and mathematics (STEM). Led by Earth scientists the Program awarded scholarships to students in their junior or senior years majoring in computer science, geosciences, mathematics and physics to create two cohorts of students that spent a total of four semesters in an interdisciplinary community. The program included mentoring of undergraduate students by faculty and graduate students (peer-mentoring), a sequence of three semesters of a one-credit seminar course and opportunities to engage in research activities, research seminars and other enriching academic experiences. Faculty and peer-mentoring were integrated into all parts of the scholarship activities. The one-credit seminar course, although designed to expose scholars to the diversity STEM disciplines and to highlight research options and careers in these disciplines, was thematically focused on geoscience, specifically on ocean and atmospheric science. The program resulted in increased retention rates relative to institutional averages. In this presentation we will discuss the process of establishing the program, from the original plans to its implementation, as well as the impact of this multidisciplinary approach to geoscience education at our institution and beyond. An overview of accomplishments, lessons learned and potential for best practices will be presented.

User-based Resource Design in Earth Science Education

NASA Astrophysics Data System (ADS)

Luby, M.; Haber, J.; Wittenberg, K.

2001-12-01

Reform in the classroom, and certainly in academic publishing, is greatly influenced not only by educational research, but also by direct surveys of students and instructors. This presentation looks at changes to Columbia Earthscape, www.earthscape.org, based on an ongoing series of evaluation and testing measures. Two years ago, the Earthscape project was introduced as a central online resource. It aimed to select and make available authoritative materials from all the disciplines that constitute Earth-system science. Its design harnessed the dynamics of the Web and the interrelatedness of research, education, and public policy. In response to substantial class tests, involving five universities in the United States and abroad, three focus groups of geoscience faculty and librarians, user feedback, internal editorial-board review, and extensive consultation with colleagues in commercial and nonprofit educational publishing, Earthscape is implementing broad changes in design and content. These include arranging the site into sections that correspond to user profiles (scientist, policy-maker, teacher, and student), providing easier search or browsing (by research area, policy content, or lesson concept), and streamlining the presentation of links among our resources. These changes are implemented through more advanced searching capabilities, greater specificity of content metatags, and an overall increase in content from journals, books, and original material. The metatags now include all core geoscience disciplines or a range of pertinent issues (such as climate change, geologic hazards, and pollution). Reflecting the evaluation by librarians, Earthscape's revised interface will permit users to begin with a primary area of interest based on who they are, their "profile." They can then either browse the site's entire holdings in that area, perform searches within each area, or follow the extensive hyperlinks to explore connections to other areas and user needs. Another two focus groups consisting of undergraduate geoscience teaching faculty brought about a rearrangement of hyperlinked resources within course-module pages. This involved less-cluttered hot-linking in running text and uniform lists of video and images links and research links at the end of all modules. Finally, after analyzing the results of a survey questionnaire administered to hundreds of students, we increased and revised content metatags to produce more specific search returns and redistributed lists of annotated links throughout the site. We are also are continuing to seek more full-text content, including original student research and exposition.

Recently Identified Changes to the Demographics of the Current and Future Geoscience Workforce

NASA Astrophysics Data System (ADS)

Wilson, C. E.; Keane, C. M.; Houlton, H. R.

2014-12-01

The American Geosciences Institute's (AGI) Geoscience Workforce Program collects and analyzes data pertaining to the changes in the supply, demand, and training of the geoscience workforce. Much of these trends are displayed in detail in AGI's Status of the Geoscience Workforce reports. In May, AGI released the Status of the Geoscience Workforce 2014, which updates these trends since the 2011 edition of this report. These updates highlight areas of change in the education of future geoscientists from K-12 through graduate school, the transition of geoscience graduates into early-career geoscientists, the dynamics of the current geoscience workforce, and the future predictions of the changes in the availability of geoscience jobs. Some examples of these changes include the increase in the number of states that will allow a high school course of earth sciences as a credit for graduation and the increasing importance of two-year college students as a talent pool for the geosciences, with over 25% of geoscience bachelor's graduates attending a two-year college for at least a semester. The continued increase in field camp hinted that these programs are at or reaching capacity. The overall number of faculty and research staff at four-year institutions increased slightly, but the percentages of academics in tenure-track positions continued to slowly decrease since 2009. However, the percentage of female faculty rose in 2013 for all tenure-track positions. Major geoscience industries, such as petroleum and mining, have seen an influx of early-career geoscientists. Demographic trends in the various industries in the geoscience workforce forecasted a shortage of approximately 135,000 geoscientists in the next decade—a decrease from the previously predicted shortage of 150,000 geoscientists. These changes and other changes identified in the Status of the Geoscience Workforce will be addressed in this talk.

Not Business-as-Usual: Resetting Expectations for Recruitment, Engagement & Professional Development of Today's URM in Geosciences

NASA Astrophysics Data System (ADS)

Auzenne, K.; Teranes, J. L.

2017-12-01

"The significant problems we have cannot be solved at the same level of thinking with which we created them." - Albert Einstein. In order to successfully recruit and retain today's URM in geosciences, we must think critically and strategically about how opportunities for professional engagement and skills-building are marketed, structured and implemented at various stages of an individual's career, and how those opportunities may be viewed and/or experienced differently by URM students and professionals. This presentation will discuss how modern professional development strategies for URMs should include: (1) clearly defined expectations that acknowledge cultural differences and challenges; (2) supportive exposure to experiences and individuals, such as role models, mentors and potential advisors; (3) constructive skill-building experiences that foster confidence and a sense of belonging, and (4) a demonstrated institutional commitment to diversity and inclusion from leadership that translates into visible resources and support. The presentation will highlight examples of these efforts and outcomes at the Scripps Institution of Oceanography, including the Scripps Undergraduate Research Fellowship (SURF) Program, a NSF-funded Research Experiences for Undergraduates (REU). With a commitment to enhancing diversity and inclusion, the SURF program has used the strategies above to help recruit and retain URM, women and veterans in graduate school and careers in the geosciences.

Geoscience on television: a review of science communication literature in the context of geosciences

NASA Astrophysics Data System (ADS)

Hut, Rolf; Land-Zandstra, Anne M.; Smeets, Ionica; Stoof, Cathelijne R.

2016-06-01

Geoscience communication is becoming increasingly important as climate change increases the occurrence of natural hazards around the world. Few geoscientists are trained in effective science communication, and awareness of the formal science communication literature is also low. This can be challenging when interacting with journalists on a powerful medium like TV. To provide geoscience communicators with background knowledge on effective science communication on television, we reviewed relevant theory in the context of geosciences and discuss six major themes: scientist motivation, target audience, narratives and storytelling, jargon and information transfer, relationship between scientists and journalists, and stereotypes of scientists on TV. We illustrate each theme with a case study of geosciences on TV and discuss relevant science communication literature. We then highlight how this literature applies to the geosciences and identify knowledge gaps related to science communication in the geosciences. As TV offers a unique opportunity to reach many viewers, we hope this review can not only positively contribute to effective geoscience communication but also to the wider geoscience debate in society.

Towards a Conceptual Design of a Cross-Domain Integrative Information System for the Geosciences

NASA Astrophysics Data System (ADS)

Zaslavsky, I.; Richard, S. M.; Valentine, D. W.; Malik, T.; Gupta, A.

2013-12-01

As geoscientists increasingly focus on studying processes that span multiple research domains, there is an increased need for cross-domain interoperability solutions that can scale to the entire geosciences, bridging information and knowledge systems, models, software tools, as well as connecting researchers and organization. Creating a community-driven cyberinfrastructure (CI) to address the grand challenges of integrative Earth science research and education is the focus of EarthCube, a new research initiative of the U.S. National Science Foundation. We are approaching EarthCube design as a complex socio-technical system of systems, in which communication between various domain subsystems, people and organizations enables more comprehensive, data-intensive research designs and knowledge sharing. In particular, we focus on integrating 'traditional' layered CI components - including information sources, catalogs, vocabularies, services, analysis and modeling tools - with CI components supporting scholarly communication, self-organization and social networking (e.g. research profiles, Q&A systems, annotations), in a manner that follows and enhances existing patterns of data, information and knowledge exchange within and across geoscience domains. We describe an initial architecture design focused on enabling the CI to (a) provide an environment for scientifically sound information and software discovery and reuse; (b) evolve by factoring in the impact of maturing movements like linked data, 'big data', and social collaborations, as well as experience from work on large information systems in other domains; (c) handle the ever increasing volume, complexity and diversity of geoscience information; (d) incorporate new information and analytical requirements, tools, and techniques, and emerging types of earth observations and models; (e) accommodate different ideas and approaches to research and data stewardship; (f) be responsive to the existing and anticipated needs of researchers and organizations representing both established and emerging CI users; and (g) make best use of NSF's current investment in the geoscience CI. The presentation will focus on the challenges and methodology of EarthCube CI design, in particular on supporting social engagement and interaction between geoscientists and computer scientists as a core function of EarthCube architecture. This capability must include mechanisms to not only locate and integrate available geoscience resources, but also engage individuals and projects, research products and publications, and enable efficient communication across many EarthCube stakeholders leading to long-term institutional alignment and trusted collaborations.

Number of women faculty in the geosciences increasing, but slowly

NASA Astrophysics Data System (ADS)

Wolfe, Cecily J.

Why are there so few women faculty in the geosciences, while there are large numbers of women undergraduate and graduate students? According to National Science Foundation (NSF) estimates [e.g.,NSF, 1996] for 1995 in the Earth, atmospheric, and oceanic sciences, women made up 34% of the bachelor's degrees awarded, 35% of the graduate students enrolled, and 22% of the doctorates granted. Yet progress has been slower in achieving adequate representation of women geoscientists in academia, where women represent only 12% of the faculty. The barriers confronting the advancement of women scientists are complex and difficult to unravel. Proposed factors include cultural stereotypes, childhood socialization, lack of women mentors and role models, lack of critical mass, family responsibilities, dual-career-couple status, isolation from collegial networks, different research and publishing strategy, and less adequate access to institutional resources [c.f., Widnall, 1988; Zuckerman et al., 1991].

Mentored undergraduate research in the geosciences

NASA Astrophysics Data System (ADS)

Judge, Shelley; Pollock, Meagen; Wiles, Greg; Wilson, Mark

2012-09-01

There is little argument about the merits of undergraduate research, but it can seem like a complex, resource-intensive endeavor [e.g., Laursen et al., 2010; Lopatto, 2009; Hunter et al., 2006]. Although mentored undergraduate research can be challenging, the authors of this feature have found that research programs are strengthened when students and faculty collaborate to build new knowledge. Faculty members in the geology department at The College of Wooster have conducted mentored undergraduate research with their students for more than 60 years and have developed a highly effective program that enhances the teaching, scholarship, and research of our faculty and provides life-changing experiences for our students. Other colleges and universities have also implemented successful mentored undergraduate research programs in the geosciences. For instance, the 18 Keck Geology Consortium schools (http://keckgeology.org/), Princeton University, and other institutions have been recognized for their senior capstone experiences by U.S. News & World Report.

Design and Applications of a GeoSemantic Framework for Integration of Data and Model Resources in Hydrologic Systems

NASA Astrophysics Data System (ADS)

Elag, M.; Kumar, P.

2016-12-01

Hydrologists today have to integrate resources such as data and models, which originate and reside in multiple autonomous and heterogeneous repositories over the Web. Several resource management systems have emerged within geoscience communities for sharing long-tail data, which are collected by individual or small research groups, and long-tail models, which are developed by scientists or small modeling communities. While these systems have increased the availability of resources within geoscience domains, deficiencies remain due to the heterogeneity in the methods, which are used to describe, encode, and publish information about resources over the Web. This heterogeneity limits our ability to access the right information in the right context so that it can be efficiently retrieved and understood without the Hydrologist's mediation. A primary challenge of the Web today is the lack of the semantic interoperability among the massive number of resources, which already exist and are continually being generated at rapid rates. To address this challenge, we have developed a decentralized GeoSemantic (GS) framework, which provides three sets of micro-web services to support (i) semantic annotation of resources, (ii) semantic alignment between the metadata of two resources, and (iii) semantic mediation among Standard Names. Here we present the design of the framework and demonstrate its application for semantic integration between data and models used in the IML-CZO. First we show how the IML-CZO data are annotated using the Semantic Annotation Services. Then we illustrate how the Resource Alignment Services and Knowledge Integration Services are used to create a semantic workflow among TopoFlow model, which is a spatially-distributed hydrologic model and the annotated data. Results of this work are (i) a demonstration of how the GS framework advances the integration of heterogeneous data and models of water-related disciplines by seamless handling of their semantic heterogeneity, (ii) an introduction of new paradigm for reusing existing and new standards as well as tools and models without the need of their implementation in the Cyberinfrastructures of water-related disciplines, and (iii) an investigation of a methodology by which distributed models can be coupled in a workflow using the GS services.

Porphyry copper deposits of the world: database, maps, and preliminary analysis

USGS Publications Warehouse

Singer, Donald A.; Berger, Vladimir I.; Moring, Barry C.

2002-01-01

Mineral deposit models are important in exploration planning and quantitative resource assessments for two reasons: (1) grades and tonnages among deposit types are significantly different, and (2) many types occur in different geologic settings that can be identified from geologic maps. Mineral deposit models are the keystone in combining the diverse geoscience information on geology, mineral occurrences, geophysics, and geochemistry used in resource assessments and mineral exploration. Far too few thoroughly explored mineral deposits are available in most local areas for reliable identification of the important geoscience variables or for robust estimation of undiscovered deposits—thus we need mineral-deposit models. Globally based deposit models, such as those presented here, allow recognition of important features because the global models demonstrate how common different features are. Well-designed and -constructed deposit models allow geologists to know from observed geologic environments the possible mineral deposit types that might exist, and allow economists to determine the possible economic viability of these resources in the region. Thus, mineral deposit models play the central role in transforming geoscience information to a form useful to policy makers. The foundation of mineral deposit models is information about known deposits—the purpose of this publication is to make this kind of information available in digital form for a group of porphyry copper deposits. This publication contains a computer file of information on porphyry copper deposits around the world. It also presents new grade and tonnage models for three subtypes of porphyry copper deposits, maps showing locations and general ages of these deposits, and a preliminary analysis with a number of figures summarizing many of the properties of these porphyry-style deposits. These summaries can be considered a new, quantified, form of most parts of descriptive models such as those in Cox and Singer (1986). The value of this information and analyses depends critically on the consistent manner of data gathering. For this reason, we first discuss the rules used in this compilation. Next the fields of the data file are considered. Finally, we discuss some of the things that can be done with the data.

Sediment-Hosted Zinc-Lead Deposits of the World - Database and Grade and Tonnage Models

USGS Publications Warehouse

Singer, Donald A.; Berger, Vladimir I.; Moring, Barry C.

2009-01-01

This report provides information on sediment-hosted zinc-lead mineral deposits based on the geologic settings that are observed on regional geologic maps. The foundation of mineral-deposit models is information about known deposits. The purpose of this publication is to make this kind of information available in digital form for sediment-hosted zinc-lead deposits. Mineral-deposit models are important in exploration planning and quantitative resource assessments: Grades and tonnages among deposit types are significantly different, and many types occur in different geologic settings that can be identified from geologic maps. Mineral-deposit models are the keystone in combining the diverse geoscience information on geology, mineral occurrences, geophysics, and geochemistry used in resource assessments and mineral exploration. Too few thoroughly explored mineral deposits are available in most local areas for reliable identification of the important geoscience variables, or for robust estimation of undiscovered deposits - thus, we need mineral-deposit models. Globally based deposit models allow recognition of important features because the global models demonstrate how common different features are. Well-designed and -constructed deposit models allow geologists to know from observed geologic environments the possible mineral-deposit types that might exist, and allow economists to determine the possible economic viability of these resources in the region. Thus, mineral-deposit models play the central role in transforming geoscience information to a form useful to policy makers. This publication contains a computer file of information on sediment-hosted zinc-lead deposits from around the world. It also presents new grade and tonnage models for nine types of these deposits and a file allowing locations of all deposits to be plotted in Google Earth. The data are presented in FileMaker Pro, Excel and text files to make the information available to as many as possible. The value of this information and any derived analyses depends critically on the consistent manner of data gathering. For this reason, we first discuss the rules applied in this compilation. Next, the fields of the data file are considered. Finally, we provide new grade and tonnage models that are, for the most part, based on a classification of deposits using observable geologic units from regional-scaled maps.

Porphyry copper deposits of the world: database, map, and grade and tonnage models

USGS Publications Warehouse

Singer, Donald A.; Berger, Vladimir Iosifovich; Moring, Barry C.

2005-01-01

Mineral deposit models are important in exploration planning and quantitative resource assessments for two reasons: (1) grades and tonnages among deposit types are significantly different, and (2) many types occur in different geologic settings that can be identified from geologic maps. Mineral deposit models are the keystone in combining the diverse geoscience information on geology, mineral occurrences, geophysics, and geochemistry used in resource assessments and mineral exploration. Too few thoroughly explored mineral deposits are available in most local areas for reliable identification of the important geoscience variables or for robust estimation of undiscovered deposits-thus we need mineral-deposit models. Globally based deposit models allow recognition of important features because the global models demonstrate how common different features are. Well-designed and -constructed deposit models allow geologists to know from observed geologic environments the possible mineral deposit types that might exist, and allow economists to determine the possible economic viability of these resources in the region. Thus, mineral deposit models play the central role in transforming geoscience information to a form useful to policy makers. The foundation of mineral deposit models is information about known deposits-the purpose of this publication is to make this kind of information available in digital form for porphyry copper deposits. This report is an update of an earlier publication about porphyry copper deposits. In this report we have added 84 new porphyry copper deposits and removed 12 deposits. In addition, some errors have been corrected and a number of deposits have had some information, such as grades, tonnages, locations, or ages revised. This publication contains a computer file of information on porphyry copper deposits from around the world. It also presents new grade and tonnage models for porphyry copper deposits and for three subtypes of porphyry copper deposits and a map showing the location of all deposits. The value of this information and any derived analyses depends critically on the consistent manner of data gathering. For this reason, we first discuss the rules used in this compilation. Next, the fields of the data file are considered. Finally, we provide new grade and tonnage models.

AGU Pathfinder: Career and Professional Development Resources for Earth and Space Scientists

NASA Astrophysics Data System (ADS)

Harwell, D. E.; Asher, P. M.; Hankin, E. R.; Janick, N. G.; Marasco, L.

2017-12-01

The American Geophysical Union (AGU) is committed to inspiring and educating present and future generations of diverse, innovative, and creative Earth and space scientists. To meet our commitment, AGU provides career and educational resources, webinars, mentoring, and support for students and professionals at each level of development to reduce barriers to achievement and to promote professional advancement. AGU is also working with other organizations and educational institutions to collaborate on projects benefiting the greater geoscience community. The presentation will include an overview of current Pathfinder efforts, collaborative efforts, and an appeal for additional partnerships.

ICP-MS and Planetary Geosciences

NASA Astrophysics Data System (ADS)

Davenport, J. D.

2014-01-01

This article, describing inductively coupled plasma mass spectrometry, is one in a series of articles, "Instruments of Cosmochemistry," highlighting the essential tools and amazing technology used by talented scientists seeking to unravel how the Solar System formed. You will find information on how the instrument works as well as how it is helping new discoveries come to light.

"Kahua A'o"--A Learning Foundation: Using Hawaiian Language Newspaper Articles for Earth Science Professional Development

ERIC Educational Resources Information Center

Chinn, Pauline W. U; Businger, Steven; Lance, Kelly; Ellinwood, Jason K.; Stone, J. Kapomaika'i; Spencer, Lindsey; McCoy, Floyd W.; Nogelmeier, M. Puakea; Rowland, Scott K.

2014-01-01

"Kahua A'o," a National Science Foundation Opportunities for Enhancing Diversity in the Geosciences project, seeks to prepare educators to address issues of underrepresentation of Native Hawaiian students in Earth and Space Science (ESS) and science, technology, engineering, and mathematics (STEM) fields. An interdisciplinary team…

Incorporating Concept Mapping in Project-Based Learning: Lessons from Watershed Investigations

ERIC Educational Resources Information Center

Rye, James; Landenberger, Rick; Warner, Timothy A.

2013-01-01

The concept map tool set forth by Novak and colleagues is underutilized in education. A meta-analysis has encouraged teachers to make extensive use of concept mapping, and researchers have advocated computer-based concept mapping applications that exploit hyperlink technology. Through an NSF sponsored geosciences education grant, middle and…

Sparking Conversations about Graduate Programs in Geoscience Education Research

ERIC Educational Resources Information Center

McNeal, Karen S.; Petcovic, Heather L.

2017-01-01

The calls for a college-educated science and technology workforce, as well as a scientifically literate citizenry, have led to a demand for higher education faculty prepared in discipline-based education research (DBER). These faculty members conduct research on teaching and learning in the context of a specific discipline, including the…

Looking in the Right Places: Minority-Serving Institutions as Sources of Diverse Earth Science Learners

ERIC Educational Resources Information Center

McDaris, John R.; Manduca, Cathryn A.; Iverson, Ellen R.; Orr, Cailin Huyck

2017-01-01

Despite gains over the last decade, the geoscience student population in the United States today continues to lag other science, technology, engineering, and mathematics disciplines in terms of diversity. Minority-serving institutions (MSIs) can play an important role in efforts to broaden underrepresented student engagement with Earth Science…

Pathways to the Geosciences Summer High School Program: A Ten-Year Evaluation

ERIC Educational Resources Information Center

Carrick, Tina L.; Miller, Kate C.; Hagedorn, Eric A.; Smith-Konter, Bridget R.; Velasco, Aaron A.

2016-01-01

The high demand for scientists and engineers in the workforce means that there is a continuing need for more strategies to increase student completion in science, technology, engineering, and mathematics (STEM) majors. The challenge lies in finding and enacting effective strategies to increase students' completion of STEM degrees and in recruiting…

Development of a geoscience education book with schoolchildren from low STEM engagement areas

NASA Astrophysics Data System (ADS)

Boyd, Alex; McAuliffe, Fergus

2017-04-01

Crucial career-related concepts and attitudes are first formed in childhood though different phases: Fantasy (age 4-10 years), Interest (age (age 11-12 years) and Capacity (age 13-14 years). Parents are major influencers in high school subject choice and ultimately career choice. Despite bring aware of the importance of STEM, 68% of Irish parents feel uninformed with regards to advising on career choices for their children. In response to this, the Science Apprentice is a series of children's books, showcasing the importance of STEM in today's society. Developed by University College Dublin, and circulated with an Irish national newspaper, this series was directed at children in elementary school (7-12 year olds) and was written to inform the first conceptions of STEM career pathways through dynamic visuals, intriguing stories and creative expressions of knowledge that relates to STEM literacy. Furthermore, the Science Apprentice series was created to offer parents a level of confidence and understanding in STEM and STEM career opportunities. Despite outreach efforts by many geoscience academics and institutions, applied geoscience remains somewhat invisible in society, with most members of the public lacking any firm familiarity with the bedrock on which they live or the resources that it holds. Here we present an overview of the Science Apprentice book series, with particular emphasis on the Energy and Resources book edition. This edition was developed in conjunction with geoscientists from the Irish Centre for Research in Applied Geoscience (iCRAG), and covered a wide range of applied geoscience topics, such as renewable and non-renewable energy sources, raw materials, engineering and the career paths of young researchers working in the geosciences. A key target audience for this book was families in low STEM engagement areas and low internet broadband connectivity areas. In this presentation we will outline how the book was developed by working with schools from low STEM engagement and rural areas, and how the primary audience of the book (7-12 year olds) was directly involved in the content development, character design and "try at home" activities that feature in the book. This was done in two steps: first through a series of workshops led by elementary STEM teaching researchers and trainers, and facilitated by science communicators; and second through a field trip to a local mine where a tour and community debate by the schoolchildren on windfarm development took place. In total, 75,000 books were circulated with the national newspaper, which saw a 6% increase in circulation at the distribution point of sale due to the books. We will also present the evaluation findings, which included focus groups with parents, in-depth interviews with teachers, and national surveys with adults. For example, 93% of parents felt that the Science Apprentice books made their children more interested in science than they were before. The presence of Irish research examples was found to shift the assumption that major scientific discoveries only take place abroad. In this presentation we will also share some critical reflections on the successes and challenges of the programme.

Why did you decide to become a Geoscience Major: A Critical Incident Study for the Development of Recruiting Programs for Inspiring Interests in the Geosciences Amongst Pre-College Students

NASA Astrophysics Data System (ADS)

Carrick, T. L.; Miller, K. C.; Levine, R.; Martinez-Sussmann, C.; Velasco, A. A.

2011-12-01

Anecdotally, it is often stated that the majority of students that enter the geosciences usually do so sometime after their initial entrance into college. With the objective of providing concrete and useful information for individuals developing programs for inspiring interest in the Geosciences amongst pre-college students and trying to increase the number of freshman Geoscience majors, we conducted a critical incident study. Twenty-two students, who were undergraduate or graduate Geoscience majors, were asked, "Why did you decide to major in the Geosciences?" in a series of interviews. Their responses were then used to identify over 100 critical incidents, each of which described a specific behavior that was causally responsible for a student's choice to major in Geoscience. Using these critical incidents, we developed a preliminary taxonomy that is comprised of three major categories: Informal Exposure to the Geosciences (e.g., outdoor experiences, family involvement), Formal Exposure to the Geosciences (e.g., academic experiences, program participation) and a Combined Informal and Formal Exposure (e.g., media exposure). Within these three main categories we identified thirteen subcategories. These categories and subcategories, describe, classify, and provide concrete examples of strategies that were responsible for geosciences career choices. As a whole, the taxonomy is valuable as a new, data-based guide for designing geosciences recruitment programs for the pre-college student population.

Development of industrial minerals in Colorado

USGS Publications Warehouse

Arbogast, Belinda F.; Knepper, Daniel H.; Langer, William H.; Cappa, James A.; Keller, John W.; Widmann, Beth L.; Ellefsen, Karl J.; Klein, Terry L.; Lucius, Jeffrey E.; Dersch, John S.

2011-01-01

Technology and engineering have helped make mining safer and cleaner for both humans and the environment. Inevitably, mineral development entails costs as well as benefits. Developing a mine is an environmental, engineering, and planning challenge that must conform to many Federal, State, and local regulations. Community collaboration, creative design, and best management practices of sustainability and biodiversity can be positive indicators for the mining industry. A better understanding of aesthetics, culture, economics, geology, climate, vegetation and wildlife, topography, historical significance, and regional land planning is important in resolving land-use issues and managing mineral resources wisely. Ultimately, the consuming public makes choices about product use (including water, food, highways, housing, and thousands of other items) that influence operations of the mineral industry. Land planners, resource managers, earth scientists, designers, and public groups have a responsibility to consider sound scientific information, society's needs, and community appeals in making smart decisions concerning resource use and how complex landscapes should change. An effort to provide comprehensive geosciences data for land management agencies in central Colorado was undertaken in 2003 by scientists of the U.S. Geological Survey and the Colorado Geological Survey. This effort, the Central Colorado Assessment Project, addressed a variety of land-use issues: an understanding of the availability of industrial and metallic rocks and minerals, the geochemical and environmental effects of historic mining activity on surface water and groundwater, and the geologic controls on the availability and quality of groundwater. The USDA Forest Service and other land management agencies have the opportunity to contribute to the sustainable management of natural aggregate and other mineral resources through the identification and selective development of mineral resources and the reclamation of mines on lands that they administer. The information in this Circular will help them carry out that task.

Developing the Next Generation of Inspired and Enthusiastic Young African Scientists: Insights from the First Ten Years of AfricaArray

NASA Astrophysics Data System (ADS)

Manzi, M. S.; Webb, S. J.; Durrheim, R. J.; Gibson, R.

2016-12-01

The African continent is endowed with a wealth of resources that are the focus of vigorous exploration by international mining companies. However, it is unfortunate that many African countries have been unable to capitalize on resource development due to a lack of expertise in research, exploration, resource management and develop their mineral deposits. The capacity to develop natural resources in Africa is, inextricably linked to the ability to fully develop intellectual capacity. Thus, training young African geoscientists to investigate and manage Africa's natural resources, and developing scientific programs about Africa resources, their settings, controls and origins, should lie at the heart of all African universities. Ten years in to the AfricaArray program, it is worth reviewing some of the insights and successes we have gained. In Africa, there is a lack of knowledge of what a "scientist" is and University is often viewed as a continuation of high school. With no real exposure to research, students don't understand the huge difference between high school and university, and they treat the university as a high school. One way to mitigate this may be to include undergraduate research opportunities in the summer break but funding is difficult to allocate. This observation highlights the need to critically review our approach to research, teaching and learning, and social engagement at school level. At University level a key focus has been the development of capacity through international collaborative research and training. The School of Geosciences, at Wits University, is already the leading institution in Africa for its breadth of geosciences research and training, and the applied nature of its research, being ranked in the top 1% of institutions worldwide in its field. It is currently a lead partner in flagship international research geophysics programme focused on Africa - the AfricaArray Field School and AfricaArray Programme. Field school has spawned other developing field schools throughout Africa.

Geology for Global Development: Training young geoscientists to communicate and do effective disaster risk reduction in the developing world

NASA Astrophysics Data System (ADS)

Gill, J. C.

2012-04-01

Geoscientists have a crucial role to play in improving disaster risk reduction and supporting communities to build resilience and reduce vulnerability. Across the world millions live in severe poverty, without access to many of the basic needs that are often taken for granted - a clean water supply, a reliable food source, safe shelter and suitable infrastructure. This lack of basic needs results in communities being particularly vulnerable to devastating natural hazards, such as floods, earthquakes, volcanic eruptions and landslides. Here we discuss two major gaps which can limit the engagement of geoscience students and recent graduates in the serious debates surrounding resilience and effective disaster risk reduction: (i) Geoscience undergraduate and postgraduate courses rarely give students the opportunity to engage with issues such as vulnerability, sustainability, knowledge exchange and cross-cultural communication. (ii) There are very few opportunities for geoscience students to gain experience in this sector through UK or overseas placements. Geology for Global Development (GfGD), established in 2011, is starting to work with UK students and recent graduates to fill these gaps. GfGD aims to inspire and engage young geoscientists, supporting them to apply their interdisciplinary knowledge and skills to generate solutions and resources which support NGOs, empower communities and help build resilience to natural hazards. This is being and will be done through: (i) active university groups hosting seminars and discussion groups; (ii) blog articles; (iii) opportunities to contribute to technical papers; (iv) workshops and conferences; and (v) UK and overseas placements. GfGD seeks to play a key role in the training and development of geoscience graduates with the necessary 'soft-skills' and opportunities to make an important contribution to improving disaster risk reduction, fighting poverty and improving people's lives.

Geoscience on television: a review of science communication literature in the context of geosciences

NASA Astrophysics Data System (ADS)

Hut, Rolf; Land-Zandstra, Anne; Smeets, Ionica; Stoof, Cathelijne

2016-04-01

Geoscience communication is becoming increasingly important as climate change increases the occurrence of natural hazards around the world. Few geoscientists are trained in effective science communication, and awareness of the formal science communication literature is also low. This can be challenging when interacting with journalists on a powerful medium like TV. To provide geoscience communicators with background knowledge on effective science communication on television, we reviewed relevant theory in the context of geosciences and discuss six major themes: scientist motivation, target audience, narratives and storytelling, jargon and information transfer, relationship between scientists and journalists, and stereotypes of scientists on TV. We illustrate each theme with a case study of geosciences on TV and discuss relevant science communication literature. We then highlight how this literature applies to the geosciences and identify knowledge gaps related to science communication in the geosciences. As TV offers a unique opportunity to reach many viewers, we hope this review can not only positively contribute to effective geoscience communication but also to the wider geoscience debate in society. This work is currently under review for publication in Hydrology and Earth System Sciences (HESS)

Geoscience Academic Provenance: A Theoretical Framework for Understanding Geoscience Students' Pathways

NASA Astrophysics Data System (ADS)

Houlton, H.; Keane, C.

2012-04-01

The demand and employment opportunities for geoscientists in the United States are projected to increase 23% from 2008 to 2018 (Gonzales, 2011). Despite this trend, there is a disconnect between undergraduate geoscience students and their desire to pursue geoscience careers. A theoretical framework was developed to understand the reasons why students decide to major in the geosciences and map those decisions to their career aspirations (Houlton, 2010). A modified critical incident study was conducted to develop the pathway model from 17, one-hour long semi-structured interviews of undergraduate geoscience majors from two Midwest Research Institutions (Houlton, 2010). Geoscience Academic Provenance maps geoscience students' initial interests, entry points into the major, critical incidents and future career goals as a pathway, which elucidates the relationships between each of these components. Analyses identified three geoscience student population groups that followed distinct pathways: Natives, Immigrants and Refugees. A follow up study was conducted in 2011 to ascertain whether these students continued on their predicted pathways, and if not, reasons for attrition. Geoscientists can use this framework as a guide to inform future recruitment and retention initiatives and target these geoscience population groups for specific employment sectors.

Geoscience Workforce Development at UNAVCO: Leveraging the NSF GAGE Facility

NASA Astrophysics Data System (ADS)

Morris, A. R.; Charlevoix, D. J.; Miller, M.

2013-12-01

Global economic development demands that the United States remain competitive in the STEM fields, and developing a forward-looking and well-trained geoscience workforce is imperative. According to the Bureau of Labor Statistics, the geosciences will experience a growth of 19% by 2016. Fifty percent of the current geoscience workforce is within 10-15 years of retirement, and as a result, the U.S. is facing a gap between the supply of prepared geoscientists and the demand for well-trained labor. Barring aggressive intervention, the imbalance in the geoscience workforce will continue to grow, leaving the increased demand unmet. UNAVCO, Inc. is well situated to prepare undergraduate students for placement in geoscience technical positions and advanced graduate study. UNAVCO is a university-governed consortium facilitating research and education in the geosciences and in addition UNAVCO manages the NSF Geodesy Advancing Geosciences and EarthScope (GAGE) facility. The GAGE facility supports many facets of geoscience research including instrumentation and infrastructure, data analysis, cyberinfrastructure, and broader impacts. UNAVCO supports the Research Experiences in the Solid Earth Sciences for Students (RESESS), an NSF-funded multiyear geoscience research internship, community support, and professional development program. The primary goal of the RESESS program is to increase the number of historically underrepresented students entering graduate school in the geosciences. RESESS has met with high success in the first 9 years of the program, as more than 75% of RESESS alumni are currently in Master's and PhD programs across the U.S. Building upon the successes of RESESS, UNAVCO is launching a comprehensive workforce development program that will network underrepresented groups in the geosciences to research and opportunities throughout the geosciences. This presentation will focus on the successes of the RESESS program and plans to expand on this success with broader workforce development efforts.

How Accessible Are the Geosciences? a Study of Professionally Held Perceptions and What They Mean for the Future of Geoscience Workforce Development

NASA Astrophysics Data System (ADS)

Atchison, C.; Libarkin, J. C.

2014-12-01

Individuals with disabilities are not entering pathways leading to the geoscience workforce; the reasons for which continue to elude access-focused geoscience educators. While research has focused on barriers individuals face entering into STEM disciplines, very little research has considered the role that practitioner perceptions play in limiting access and accommodation to scientific disciplines. The authors argue that changing the perceptions within the geoscience community is an important step to removing barriers to entry into the myriad fields that make up the geosciences. This paper reports on an investigation of the perceptions that geoscientist practitioners hold about opportunities for engagement in geoscience careers for people with disabilities. These perspectives were collected through three separate iterations of surveys at three professional geoscience meetings in the US and Australia between 2011 and 2012. Respondents were asked to indicate the extent to which individuals with specific types of disabilities would be able to perform various geoscientific tasks. The information obtained from these surveys provides an initial step in engaging the larger geoscience community in a necessary discussion of minimizing the barriers of access to include students and professionals with disabilities. The results imply that a majority of the geoscience community believes that accessible opportunities exist for inclusion regardless of disability. This and other findings suggest that people with disabilities are viewed as viable professionals once in the geosciences, but the pathways into the discipline are prohibitive. Perceptions of how individuals gain entry into the field are at odds with perceptions of accessibility. This presentation will discuss the common geoscientist perspectives of access and inclusion in the geoscience discipline and how these results might impact the future of the geoscience workforce pathway for individuals with disabilities.

Strengthening International Collaboration: Geosciences Research and Education in Developing Countries

NASA Astrophysics Data System (ADS)

Fucugauchi, J. U.

2009-05-01

Geophysical research increasingly requires global multidisciplinary approaches and global integration. Global warming, increasing CO2 levels and increased needs of mineral and energy resources emphasize impact of human activities. The planetary view of our Earth as a deeply complex interconnected system also emphasizes the need of international scientific cooperation. International collaboration presents an immense potential and is urgently needed for further development of geosciences research and education. In analyzing international collaboration a relevant aspect is the role of scientific societies. Societies organize meetings, publish journals and books and promote cooperation through academic exchange activities and can further assist communities in developing countries providing and facilitating access to scientific literature, attendance to international meetings, short and long-term stays and student and young researcher mobility. Developing countries present additional challenges resulting from limited economic resources and social and political problems. Most countries urgently require improved educational and research programs. Needed are in-depth analyses of infrastructure and human resources and identification of major problems and needs. Questions may include what are the major limitations and needs in research and postgraduate education in developing countries? what and how should international collaboration do? and what are the roles of individuals, academic institutions, funding agencies, scientific societies? Here we attempt to examine some of these questions with reference to case examples and AGU role. We focus on current situation, size and characteristics of research community, education programs, facilities, economic support, and then move to perspectives for potential development in an international context.

Reaching the Next Generation of College Students via Their Digital Devices.

NASA Astrophysics Data System (ADS)

Whitmeyer, S. J.; De Paor, D. G.; Bentley, C.

2015-12-01

Current college students attended school during a decade in which many school districts banned cellphones from the classroom or even from school grounds. These students are used to being told to put away their mobile devices and concentrate on traditional classroom activities such as watching PowerPoint presentations or calculating with pencil and paper. However, due to a combination of parental security concerns and recent education research, schools are rapidly changing policy and embracing mobile devices for ubiquitous learning opportunities inside and outside of the classroom. Consequently, many of the next generation of college students will have expectations of learning via mobile technology. We have developed a range of digital geology resources to aid mobile-based geoscience education at college level, including mapping on iPads and other tablets, "crowd-sourced" field projects, augmented reality-supported asynchronous field classes, 3D and 4D split-screen virtual reality tours, macroscopic and microscopic gigapixel imagery, 360° panoramas, assistive devices for inclusive field education, and game-style educational challenges. Class testing of virtual planetary tours shows modest short-term learning gains, but more work is needed to ensure long-term retention. Many of our resources rely on the Google Earth browser plug-in and application program interface (API). Because of security concerns, browser plug-ins in general are being phased out and the Google Earth API will not be supported in future browsers. However, a new plug-in-free API is promised by Google and an alternative open-source virtual globe called Cesium is undergoing rapid development. It already supports the main aspects of Keyhole Markup Language and has features of significant benefit to geoscience, including full support on mobile devices and sub-surface viewing and touring. The research team includes: Heather Almquist, Stephen Burgin, Cinzia Cervato, Filis Coba, Chloe Constants, Gene Cooper, Mladen Dordevic, Marissa Dudek, Brandon Fitzwater, Bridget Gomez, Tyler Hansen, Paul Karabinos, Terry Pavlis, Jen Piatek, Alan Pitts, Robin Rohrback, Bill Richards, Caroline Robinson, Jeff Rollins, Jeff Ryan, Ron Schott, Kristen St. John, and Barb Tewksbury. Supported by NSF DUE 1323419 and by Google Geo Curriculum Awards.

Rising Above the Storm: DIG TEXAS

NASA Astrophysics Data System (ADS)

Ellins, K. K.; Miller, K. C.; Bednarz, S. W.; Mosher, S.

2011-12-01

For a decade Texas educators, scientists and citizens have shown a commitment to earth science education through planning at the national and state levels, involvement in earth science curriculum and teacher professional development projects, and the creation of a model senior level capstone Earth and Space Science course first offered in 2010 - 2011. The Texas state standards for Earth and Space Science demonstrate a shift to rigorous content, career relevant skills and use of 21st century technology. Earth and Space Science standards also align with the Earth Science, Climate and Ocean Literacy framework documents. In spite of a decade of progress K-12 earth science education in Texas is in crisis. Many school districts do not offer Earth and Space Science, or are using the course as a contingency for students who fail core science subjects. The State Board for Educator Certification eliminated Texas' secondary earth science teacher certification in 2009, following the adoption of the new Earth and Space Science standards. This makes teachers with a composite teacher certification (biology, physics and chemistry) eligible to teach Earth and Space Science, as well other earth science courses (e.g., Aquatic Science, Environmental Systems/Science) even if they lack earth science content knowledge. Teaching materials recently adopted by the State Board of Education do not include Earth and Space Science resources. In July 2011 following significant budget cuts at the 20 Education Service Centers across Texas, the Texas Education Agency eliminated key staff positions in its curriculum division, including science. This "perfect storm" has created a unique opportunity for a university-based approach to confront the crisis in earth science education in Texas which the Diversity and Innovation in the Geosciences (DIG) TEXAS alliance aims to fulfill. Led by the Texas A&M University College of Geosciences and The University of Texas Jackson School of Geosciences, with initial assistance of the American Geophysical Union, the alliance comprises earth scientists and educators at higher education institutions across the state, and science teachers, united to improve earth science literacy (geoscience-earth, ocean, atmospheric, planetary, and geography) among Texas science teachers in order to attract individuals from groups underrepresented in STEM fields to pursue earth science as a career. Members of the alliance are affiliated with one of eight regional DIG TEXAS hub institutions. With an NSF planning grant, DIG TEXAS leaders created the DIG TEXAS brand, developed a project website, organized and held the first community meeting in March, 2011 at Exxon Mobil's Training Center in Houston. DIG TEXAS members have also delivered testimony to the State Board for Educator Certification in support of a new earth science teacher certification and collaborated on proposals that seek funding to support recommendations formulated at the community meeting.

Outreach to Hispanic/Latino Communities With a Spanish-Language Version of the Earthscope Website

NASA Astrophysics Data System (ADS)

López, A. M.; Stein, S.; Delaughter, J.

2005-12-01

Spanish is estimated to be the fourth language in the world based on number of speakers, the second as a vehicle of international communication and the third as an international language of politics, economics and culture. Its importance in the U.S. is illustrated by the fact that the Hispanic/Latino population is becoming the largest minority group because it has the fastest growth rate of all ethnic groups in the U.S. According to the U.S. Census Bureau, in 2004 there were ~41 million people in the U.S. (~14% of the total population) of Hispanic or Latino origin. Although the Spanish-speaking population is growing rapidly, the same cannot be said about the number of Hispanic/Latino high school and college graduates. Studies by the National Center for Education Statistics show that Hispanic/Latino students are as likely to drop out are to complete high school. Similarly, although more Hispanic/Latino students enroll in college and/or universities than a decade ago, few complete degrees. For example, in the geosciences only 3% of bachelor's degrees were granted to people identifying themselves as Hispanic or Latino. Over the last 28 years, only 263 of the 20,000 geoscience Ph.D.s awarded in the U.S. went to Hispanic Americans. Bilingual educational offerings are one technique for addressing this discrepancy. For example, scientists and research programs such as EarthScope, NASA, NOAA, and ODP frequently reach out to students and the general public using the internet. Many well-made and useful websites with scientific themes in the U.S. are available to millions of users worldwide, providing a resource that is limited or non-existent in other countries. Unfortunately, few geoscience education sites are available in languages other than English. To address this need, Earthscope is developing a Spanish version of its website describing its goals, techniques, and educational opportunities. Currently, approximately 90% of the educational content on this site (http://www.earthscope.org/education/index.php) is available in both English and Spanish. As time and resources permit, more of the site will be translated. This effort is already having an effect; in a recent Google search using the term "Ferias Científicas" (Science Fairs), EarthScope's site ranked second. Such Spanish material will hopefully have several applications relevant to Earthscope goals. They should encourage Spanish-speaking students to explore the geosciences, and help Hispanic populations become more knowledgeable about the Earth by providing information about the geologic processes and hazards in their area in a language they truly understand. In addition, such web sites can provide useful resources to people in Latin American countries, many of which have geologic processes that are an important aspect of their lives.

Geodesy and the UNAVCO Consortium: Three Decades of Innovations

NASA Astrophysics Data System (ADS)

Rowan, L. R.; Miller, M. M.; Meertens, C. M.; Mattioli, G. S.

2015-12-01

UNAVCO, a non-profit, university consortium that supports geoscience research using geodesy, began with the ingenious recognition that the nascent Global Positioning System constellation (GPS) could be used to investigate earth processes. The consortium purchased one of the first commercially available GPS receivers, Texas Instrument's TI-4100 NAVSTAR Navigator, in 1984 to measure plate deformation. This early work was highlighted in a technology magazine, GPSWorld, in 1990. Over a 30-year period, UNAVCO and the community have helped advance instrument design for mobility, flexibility, efficiency and interoperability, so research could proceed with higher precision and under ever challenging conditions. Other innovations have been made in data collection, processing, analysis, management and archiving. These innovations in tools, methods and data have had broader impacts as they have found greater utility beyond research for timing, precise positioning, safety, communication, navigation, surveying, engineering and recreation. Innovations in research have expanded the utility of geodetic tools beyond the solid earth science through creative analysis of the data and the methods. For example, GPS sounding of the atmosphere is now used for atmospheric and space sciences. GPS reflectrometry, another critical advance, supports soil science, snow science and ecological research. Some research advances have had broader impacts for society by driving innovations in hazards risk reduction, hazards response, resource management, land use planning, surveying, engineering and other uses. Furthermore, the geodetic data is vital for the design of space missions, testing and advancing communications, and testing and dealing with interference and GPS jamming. We will discuss three decades (and counting) of advances by the National Science Foundation's premiere geodetic facility, consortium and some of the many geoscience principal investigators that have driven innovations in research, instrumentation, data management, cyberinfrastructure and other applications.

An intelligent data model for the storage of structured grids

NASA Astrophysics Data System (ADS)

Clyne, John; Norton, Alan

2013-04-01

With support from the U.S. National Science Foundation we have developed, and currently maintain, VAPOR: a geosciences-focused, open source visual data analysis package. VAPOR enables highly interactive exploration, as well as qualitative and quantitative analysis of high-resolution simulation outputs using only a commodity, desktop computer. The enabling technology behind VAPOR's ability to interact with a data set, whose size would overwhelm all but the largest analysis computing resources, is a progressive data access file format, called the VAPOR Data Collection (VDC). The VDC is based on the discrete wavelet transform and their information compaction properties. Prior to analysis, raw data undergo a wavelet transform, concentrating the information content into a fraction of the coefficients. The coefficients are then sorted by their information content (magnitude) into a small number of bins. Data are reconstructed by applying an inverse wavelet transform. If all of the coefficient bins are used during reconstruction the process is lossless (up to floating point round-off). If only a subset of the bins are used, an approximation of the original data is produced. A crucial point here is that the principal benefit to reconstruction from a subset of wavelet coefficients is a reduction in I/O. Further, if smaller coefficients are simply discarded, or perhaps stored on more capacious tertiary storage, secondary storage requirements (e.g. disk) can be reduced as well. In practice, these reductions in I/O or storage can be on the order of tens or even hundreds. This talk will briefly describe the VAPOR Data Collection, and will present real world success stories from the geosciences that illustrate how progressive data access enables highly interactive exploration of Big Data.

The Elwha Science Education Project (ESEP): Engaging an Entire Community in Geoscience Education

NASA Astrophysics Data System (ADS)

Young, R. S.; Kinner, F.

2008-12-01

Native Americans are poorly represented in all science, technology and engineering fields. This under- representation results from numerous cultural, economic, and historical factors. The Elwha Science Education Project (ESEP), initiated in 2007, strives to construct a culturally-integrated, geoscience education program for Native American young people through engagement of the entire tribal community. The ESEP has developed a unique approach to informal geoscience education, using environmental restoration as a centerpiece. Environmental restoration is an increasingly important goal for tribes. By integrating geoscience activities with community tradition and history, project stakeholders hope to show students the relevance of science to their day-to-day lives. The ESEP's strength lies in its participatory structure and unique network of partners, which include Olympic National Park; the non-profit, educational center Olympic Park Institute (OPI); a geologist providing oversight and technical expertise; and the Lower Elwha Tribe. Lower Elwha tribal elders and educators share in all phases of the project, from planning and implementation to recruitment of students and discipline. The project works collaboratively with tribal scientists and cultural educators, along with science educators to develop curriculum and best practices for this group of students. Use of hands-on, place-based outdoor activities engage students and connect them with the science outside their back doors. Preliminary results from this summer's middle school program indicate that most (75% or more) students were highly engaged approximately 90% of the time during science instruction. Recruitment of students has been particularly successful, due to a high degree of community involvement. Preliminary evaluations of the ESEP's outcomes indicate success in improving the outlook of the tribe's youth towards the geosciences and science, in general. Future evaluation will be likewise participatory, incorporating student, tribal educator, and OPI views while considering sound geological content to formatively contribute to program success.

Attrition among Women and Minorities in Earth and Space Science (ESS) Graduate Programs

NASA Astrophysics Data System (ADS)

Alexander, C. J.; Hawthorne, C.; Allen, W. R.; Alvarez, R.; Geisler, J.

2001-05-01

Recent data collected by the American Geological Institute (AGI) indicates that the rate of enrollment of ethnic minorities in the geosciences has steadily declined since the 1980's, and in that time the number of geoscience degrees awarded to ethnic minorities has been fairly steady at less than 1%. Data from the National Science Foundation suggests that only 43 of 186 Universities offering an ESS program have ever graduated an ethnic minority in the history of their program. Factors contributing to these abysmal figures differ for different ethnic-minority groups. We will address institutional obstacles to graduate learning which result in above-normal attrition of ethnic-minorities in ESS graduate programs. The recent studies show an attrition rate of 70% among African American males in ESS graduate programs, while among Hispanic females the attrition rate is only 3%. Studies by sociologists have recently shown that some law schools and medical schools have traits in common with these geoscience departments in the rates at which degrees are awarded to ethnic minorities. Institutional barriers encountered by ethnic minorities in graduate schools may take many forms, but can also be as simple as a lack of community support. In the 1990's the California Institute of Technology (Caltech) made a commitment to the retention of women in their graduate and undergraduate schools. Their program included mentoring, focussed tutoring, self-esteem support groups, and other retention efforts. Under this program, the attrition rate of women has dramatically slowed. In this paper, we will discuss the AGI data, the program instituted by Caltech, possible causes of attrition among populations of Hispanic, and African American males and females, as well as potential programs to address these problems. We will also present, from the nationwide study, data on geoscience departments which have been relatively successful at retaining and graduating ethnic minorities in Earth and Space Sciences. The AGI Report on the Status of [U.S.] Academic Geoscience Departments is available online at the URL listed below.

Strength Through Options: Providing Choices for Undergraduate Education in the Geosciences

NASA Astrophysics Data System (ADS)

Furman, T.; Freeman, K. H.; Faculty, D.

2003-12-01

Undergraduate major enrollments in the Department of Geosciences at Penn State have held steady over the past 5 years despite generally declining national trends. We have successfully recruited and retained new students through intensive advising coupled with innovative curricular revision aimed to meet an array of students' educational and career goals. Our focus is on degree programs that reflect emerging interdisciplinary trends in both employment and student interest, and are designed to attract individuals from underrepresented groups. In addition to a traditional Geosciences BS program we offer a rigorous integrated Earth Sciences BS and a Geosciences BA tailored to students with interests in education and environmental law. The Earth Sciences BS incorporates course work from Geosciences, Geography and Meterology, and requires completion of an interdisciplinary minor (e.g., Climatology, Marine Sciences, Global Business Strategies). A new Geobiology BS program will attract majors with interests at the intersection of the earth and life sciences. The curriculum includes both paleontological and biogeochemical coursework, and is also tailored to accommodate pre-medicine students. We are working actively to recruit African-American students. A new minor in Science and Technology in Africa crosses disciplinary boundaries to educate students from the humanities as well as sciences. Longitudinal recruitment programs include summer research group experiences for high school students, summer research mentorships for college students, and dual undergraduate degree programs with HBCUs. Research is a fundamental component of every student's degree program. We require a capstone independent thesis as well as a field program for Geosciences and Geobiology BS students, and we encourage all students to pursue research as early as the freshman year. A new 5-year combined BS-MS program will enable outstanding students to carry their undergraduate research further before pursuing employment or doctoral programs. Enrollments in courses for non-majors have also increased substantially over the past 5 years, while those of other PSU science departments have decreased. We attribute this success to changes in pedagogic approaches, focusing on active learning exercises in large (200+) and small (<75) courses. Innovative use of an electronic personal response system has also improved attendance, enrollment and student learning in our general education courses. This approach was developed by a fixed-term faculty hire in Geoscience Education. As per our departmental strategic plan, we plan to hire again in this area to further these successes and implement new approaches to learning and teaching in our undergraduate educational programs.

Undergraduate teaching modules featuring geodesy data applied to critical social topics (GETSI: GEodetic Tools for Societal Issues)

NASA Astrophysics Data System (ADS)

Pratt-Sitaula, B. A.; Walker, B.; Douglas, B. J.; Charlevoix, D. J.; Miller, M. M.

2015-12-01

The GETSI project, funded by NSF TUES, is developing and disseminating teaching and learning materials that feature geodesy data applied to critical societal issues such as climate change, water resource management, and natural hazards (serc.carleton.edu/getsi). It is collaborative between UNAVCO (NSF's geodetic facility), Mt San Antonio College, and Indiana University. GETSI was initiated after requests by geoscience faculty for geodetic teaching resources for introductory and majors-level students. Full modules take two weeks but module subsets can also be used. Modules are developed and tested by two co-authors and also tested in a third classroom. GETSI is working in partnership with the Science Education Resource Center's (SERC) InTeGrate project on the development, assessment, and dissemination to ensure compatibility with the growing number of resources for geoscience education. Two GETSI modules are being published in October 2015. "Ice mass and sea level changes" includes geodetic data from GRACE, satellite altimetry, and GPS time series. "Imaging Active Tectonics" has students analyzing InSAR and LiDAR data to assess infrastructure earthquake vulnerability. Another three modules are in testing during fall 2015 and will be published in 2016. "Surface process hazards" investigates mass wasting hazard and risk using LiDAR data. "Water resources and geodesy" uses GRACE, vertical GPS, and reflection GPS data to have students investigating droughts in California and the High Great Plains. "GPS, strain, and earthquakes" helps students learn about infinitesimal and coseismic strain through analysis of horizontal GPS data and includes an extension module on the Napa 2014 earthquake. In addition to teaching resources, the GETSI project is compiling recommendations on successful development of geodesy curricula. The chief recommendations so far are the critical importance of including scientific experts in the authorship team and investing significant resources in data preparation (student interns can be excellent for this). GETSI also includes a research element on the way instructors adapt or adopt the resources. After publication, 4 additional testers will be recruited per module. They will provide feedback on how they choose to use the module elements in their courses.

Piloting a Geoscience Literacy Exam for Assessing Students' Understanding of Earth, Climate, Atmospheric and Ocean Science Concepts

NASA Astrophysics Data System (ADS)

Steer, D. N.; Iverson, E. A.; Manduca, C. A.

2013-12-01

This research seeks to develop valid and reliable questions that faculty can use to assess geoscience literacy across the curriculum. We are particularly interested on effects of curricula developed to teach Earth, Climate, Atmospheric, and Ocean Science concepts in the context of societal issues across the disciplines. This effort is part of the InTeGrate project designed to create a population of college graduates who are poised to use geoscience knowledge in developing solutions to current and future environmental and resource challenges. Details concerning the project are found at http://serc.carleton.edu/integrate/index.html. The Geoscience Literacy Exam (GLE) under development presently includes 90 questions. Each big idea from each literacy document can be probed using one or more of three independent questions: 1) a single answer, multiple choice question aimed at basic understanding or application of key concepts, 2) a multiple correct answer, multiple choice question targeting the analyzing to analysis levels and 3) a short essay question that tests analysis or evaluation cognitive levels. We anticipate multiple-choice scores and the detail and sophistication of essay responses will increase as students engage with the curriculum. As part of the field testing of InTeGrate curricula, faculty collected student responses from classes that involved over 700 students. These responses included eight pre- and post-test multiple-choice questions that covered various concepts across the four literacies. Discrimination indices calculated from the data suggest that the eight tested questions provide a valid measure of literacy within the scope of the concepts covered. Student normalized gains across an academic term with limited InTeGrate exposure (typically two or fewer weeks of InTeGrate curriculum out of 14 weeks) were found to average 16% gain. A small set of control data (250 students in classes from one institution where no InTeGrate curricula were used) was also collected from a larger bank of test questions. Discrimination indices across the full bank showed variation and additional work is underway to refine and field test in other settings these questions in the absence of InTeGrate curricula. When complete, faculty will be able to assemble sets of questions to track progress toward meeting literacy goals. In addition to covering geoscience content knowledge and understanding, a complementary attitudinal pre/post survey was also developed with the intent to probe InTeGrate students' ability and motivation to use their geoscience expertise to address problems of environmental sustainability. The final instruments will be made available to the geoscience education community as an assessment to be used in conjunction with InTeGrate teaching materials or as a stand-alone tool for departments to measure student learning and attitudinal gains across the major.

From Field to the Web: Management and Publication of Geoscience Samples in CSIRO Mineral Resources

NASA Astrophysics Data System (ADS)

Devaraju, A.; Klump, J. F.; Tey, V.; Fraser, R.; Reid, N.; Brown, A.; Golodoniuc, P.

2016-12-01

Inaccessible samples are an obstacle to the reproducibility of research and may cause waste of time and resources through duplication of sample collection and management. Within the Commonwealth Scientific and Industrial Research Organisation (CSIRO) Mineral Resources there are various research communities who collect or generate physical samples as part of their field studies and analytical processes. Materials can be varied and could be rock, soil, plant materials, water, and even synthetic materials. Given the wide range of applications in CSIRO, each researcher or project may follow their own method of collecting, curating and documenting samples. In many cases samples and their documentation are often only available to the sample collector. For example, the Australian Resources Research Centre stores rock samples and research collections dating as far back as the 1970s. Collecting these samples again would be prohibitively expensive and in some cases impossible because the site has been mined out. These samples would not be easily discoverable by others without an online sample catalog. We identify some of the organizational and technical challenges to provide unambiguous and systematic access to geoscience samples, and present their solutions (e.g., workflow, persistent identifier and tools). We present the workflow starting from field sampling to sample publication on the Web, and describe how the International Geo Sample Number (IGSN) can be applied to identify samples along the process. In our test case geoscientific samples are collected as part of the Capricorn Distal Footprints project, a collaboration project between the CSIRO, the Geological Survey of Western Australia, academic institutions and industry partners. We conclude by summarizing the values of our solutions in terms of sample management and publication.

A Foundational Approach to Designing Geoscience Ontologies

NASA Astrophysics Data System (ADS)

Brodaric, B.

2009-05-01

E-science systems are increasingly deploying ontologies to aid online geoscience research. Geoscience ontologies are typically constructed independently by isolated individuals or groups who tend to follow few design principles. This limits the usability of the ontologies due to conceptualizations that are vague, conflicting, or narrow. Advances in foundational ontologies and formal engineering approaches offer promising solutions, but these advanced techniques have had limited application in the geosciences. This paper develops a design approach for geoscience ontologies by extending aspects of the DOLCE foundational ontology and the OntoClean method. Geoscience examples will be presented to demonstrate the feasibility of the approach.

The Field-tested Learning Assessment Guide (FLAG): A Community Repository of Proven Alternative Assessment Instruments for STEM Education

NASA Astrophysics Data System (ADS)

Zeilik, M.; Garvin-Doxas, K.

2003-12-01

FLAG, the Field-tested Learning Assessment Guide (http://www.flaguide.org/) is a NSF funded website that offers broadly-applicable, self-contained modular classroom assessment techniques (CATs) and discipline-specific tools for STEM instructors creating new approaches to evaluate student learning, attitudes and performance. In particular, the FLAG contains proven techniques for alterative assessments---those needed for reformed, innovative STEM courses. Each tool has been developed, tested and refined in real classrooms at colleges and universities. The FLAG also contains an assessment primer, a section to help you select the most appropriate assessment technique(s) for your course goals, and other resources. In addition to references on instrument development and field-tested instruments on attitudes towards science, the FLAG also includes discipline-specific tools in Physics, Astronomy, Biology, and Mathematics. Building of the Geoscience collection is currently under way with the development of an instrument for detecting misconceptions of incoming freshmen on Space Science, which is being developed with the help of the Committee on Space Science and Astronomy of the American Association of Physics Teachers. Additional field-tested resources from the Geosciences are solicited from the community. Contributions should be sent to Michael Zeilik, zeilik@la.unm.edu. This work has been supported in part by NSF grant DUE 99-81155.

The Two-Year Colleges' Role in Building the Future Geoscience Technical Workforce

NASA Astrophysics Data System (ADS)

Wolfe, B.

2014-12-01

Careers in energy science related fields represent significant job growth in the U.S. Yet post-secondary career and technical programs have not kept pace with demand and energy science curriculum, including fundamental concepts of energy generation and environmental impact, lacks a firm position among general or career and technical education courses. Many of these emerging energy related jobs are skilled labor and entry level technical positions requiring less than a bachelor's degree. These include jobs such as solar/photovoltaic design and installation, solar water and space heating installation, energy management, efficiency and conservation auditor, environmental technician, etc. These energy related career pathways fit naturally within the geosciences discipline. Many of these jobs can be filled by individuals from HVAC, Industrial technology, welding, and electrical degree programs needing some additional specialized training and curriculum focused on fundamental concepts of energy, fossil fuel exploration and use, atmospheric pollution, energy generation, alternative energy sources, and energy conservation. Two-year colleges (2ycs) are uniquely positioned to train and fill these workforce needs as they already have existing career and technical programs and attract both recent high school graduates, as well as non-traditional students including displaced workers and returning veterans. We have established geoscience related workforce certificate programs that individuals completing the traditional industrial career and technical degrees can obtain to meet these emerging workforce needs. This presentation will discuss the role of geosciences programs at 2ycs in training these new workers, developing curriculum, and building a career/technical program that is on the forefront of this evolving industry.

A Research Experience for Undergraduates on Sustainable Land and Water Resources

NASA Astrophysics Data System (ADS)

Dalbotten, D. M.; Berthelote, A. R.; Myrbo, A.; Ito, E.; Howes, T.

2011-12-01

A new research experience for undergraduates is being piloted which supports student involvement in management of land and water resources with sustainability as the major focus. Working on two Native American reservations (Fond du Lac Band of Lake Superior Chippewa, and Confederated Salish and Kootenai Tribes of Flathead Reservation) and in conjunction with local tribal colleges, we particularly focus on management of tribal land and water resources. In this way we work to both increase the involvement of Native American students in the geosciences and support ethical partnerships for research on Native lands. Students also have the opportunity to work experimentally at the St. Anthony Falls Laboratory in conjunction with the National Center for Earth-surface Dynamics.

Teaching Structure from Motion to Undergraduates: New Learning Module for Field Geoscience Courses

NASA Astrophysics Data System (ADS)

Pratt-Sitaula, B. A.; Shervais, K.; Crosby, C. J.; Douglas, B. J.; Crosby, B. T.; Charlevoix, D. J.

2016-12-01

With photogrammetry use expanding rapidly, it is essential to integrate these methods into undergraduate geosciences courses. The NSF-funded "GEodetic Tools for Societal Issues" (GETSI) project has recently published a module for field geoscience courses called "Analyzing High Resolution Topography with TLS and SfM" (serc.carleton.edu/getsi/teaching_materials/high-rez-topo/index.html). Structure from motion (SfM) and terrestrial laser scanning (TLS) are two valuable methods for generating high-resolution topographic landscape models. In addition to teaching the basic surveying methods, the module includes several specific applications that are tied to societally important geoscience research questions. The module goals are that students will be able to: 1) design and conduct a complex TLS and/or SfM survey to address a geologic research question; 2) articulate the societal impetus for answering a given research question; and 3) justify why TLS and/or SfM is the appropriate method in some circumstances. The module includes 6 units: Unit 1-TLS Introduction, Unit 1-SfM Introduction, Unit 2 Stratigraphic Section Survey, Unit 3 Fault Scarp Survey, Unit 4 Geomorphic Change Detection Survey, and Unit 5 Summative Assessment. One or both survey methods can be taught. Instructors choose which application/s to use from Units 2-4. Unit 5 Summative Assessment is flexibly written and can be used to assess any of the learned applications or others such as dinosaur tracks or seismic trench photomosaics. Prepared data sets are also provided for courses unable to visit the field. The included SfM learning manuals may also be of interest to researchers seeking to start with SfM; these are "SfM Guide of Instructors and Investigators" and "SfM Data Exploration and Processing Manual (Agisoft)". The module is appropriate for geoscience courses with field components such as field methods, geomorphology, geophysics, tectonics, and structural geology. All GETSI modules are designed and developed by teams of faculty and content experts and undergo rigorous review and classroom testing. GETSI is a collaborative project by UNAVCO (which runs NSF's Geodetic Facility), Indiana University, and Idaho State University. The Science Education Resource Center (SERC) provides assessment and evaluation expertise and webhosting.

Writing fiction about geoscience

NASA Astrophysics Data System (ADS)

Andrews, S.

2013-12-01

Employment in geology provides excellent preparation for writing mystery novels that teach geoscience. While doing pure research at the USGS under the mentorship of Edwin D. McKee, I learned that the rigors of the scientific method could be applied not only to scientific inquiry but to any search for what is true, including the art of storytelling (the oldest and still most potent form of communication), which in turn supports science. Geoscience constructs narratives of what has happened or what might happen; hence, to communicate my findings, I must present a story. Having developed my writing skills while preparing colleague-reviewed papers (which required that I learn to set my ego aside and survive brutal critiques), the many rounds of edits required to push a novel through a publishing house were a snap. My geoscience training for becoming a novelist continued through private industry, consultancy, and academia. Employment as a petroleum geologist added the pragmatism of bottom-line economics and working to deadlines to my skill set, and nothing could have prepared me for surviving publishers' rejections and mixed reviews better than having to pitch drilling projects to jaded oil patch managers, especially just before lunchtime, when I was all that stood between them and their first martinis of the day. Environmental consulting was an education in ignorant human tricks and the politics of resource consumption gone astray. When teaching at the college level and guest lecturing at primary and secondary schools, my students taught me that nothing was going to stick unless I related the story of geoscience to their lives. When choosing a story form for my novels, I found the mystery apropos because geoscientists are detectives. Like police detectives, we work with fragmentary and often hidden evidence using deductive logic, though our corpses tend to be much, much older or not dead yet. Throughout my career, I learned that negative stereotypes about scientists are largely unwarranted and that the best way to break down communication barriers and educate the public about what we've done for them lately is to recast the scientist as the hero of the story and thus show how the fascinating work of geoscientists contributes to readers' lives. St Geo and the Dragon

The Natural Science Program at the University of New Mexico: Geosciences Play a Central Role in Preservice Teacher Training

NASA Astrophysics Data System (ADS)

Nyman, M. W.; Ellwein, A. L.; Geissman, J. W.; McFadden, L. D.; Crossey, L. J.

2007-12-01

An important component for future directions of geoscience departments is public education. The role of geoscience departments in the preparation and professional development of K-12 teachers is particularly critical, and merges with other teaching missions within the University. The importance of geoscience content for teachers (and the general public) is evident in the numerous earth science related public policy issues that are the subject of ever-increasing attention (climate change, energy resources, water utilization, etc.). The earth and space sciences are not only included in both state and federal science content education standards but are also inherently interesting to students and therefore provide an important gateway to foster interest in science as well as other scientific disciplines. For over 10 years, the Department of Earth and Planetary Sciences (EPS) at the University of New Mexico (UNM) has housed and supported the Natural Science Program (NSP), which provides science content courses and numerous programs for K-12 pre- and in-service teachers. Classes and laboratories are integrated, and are capped at 21 students in the 200-level courses, assuring an active and supportive learning environment for students who are typically science-phobic with negative or no experiences with science. Enrollments are maintained at ~150 preservice teachers per semester. The program is staffed by two lecturers, who have advanced degrees in the geosciences as well as K-12 teaching experience, and several part time instructors, including graduate students who gain valuable teaching experience through teaching in the NSP. With continued support from the department, the NSP has expanded to develop robust and functional relationships related to science teacher professional development with Sandia National Laboratories and local school districts, initiated development of a graduate certificate in science teaching and, advanced a proposal for the development of an Energy Education Program at UNM. Finally, the NSP provides a ready avenue for the incorporation of grant funded faculty research into teacher education programs, thus providing a viable and functional method for addressing broader impacts related to NSF funded programs.

New Materials for the Undergraduate Classroom to Build Pre-Service Teachers' NGSS Skills and Knowledge

NASA Astrophysics Data System (ADS)

Egger, A. E.; Awad, A. A.; Baldwin, K. A.; Birnbaum, S. J.; Bruckner, M. Z.; DeBari, S. M.; Dechaine, J.; Ebert, J. R.; Gray, K. R.; Hauge, R.; Linneman, S. R.; Monet, J.; Thomas, J.; Varrella, G.

2014-12-01

As part of InTeGrate, teams of 3 instructors at 3 different institutions developed modules that help prepare pre-service teachers to teach Earth science aligned with the NGSS. Modules were evaluated against a rubric, which addresses InTeGrate's five guiding principles, learning objectives and outcomes, assessment and measurement, resources and materials, instructional strategies and alignment. As all modules must address one or more Earth-related grand challenge facing society, develop student ability to address interdisciplinary problems, improve student understanding of the methods of geoscience, use authentic geoscience data, and incorporate systems thinking, they align well with the NGSS. Once modules passed the rubric, they were tested by the authors in their classrooms. Testing included pre- and post-assessment of geoscience literacy and assessment of student learning towards the module goal; materials were revised based on the results of testing. In "Exploring Geoscience Methods with Secondary Education Students," pre-service science teachers compare geoscientific thinking with the classic (experimental) scientific method, investigate global climate change and its impacts on human systems, and prepare an interdisciplinary lesson plan that addresses geoscience methods in context of a socioscientific issue. In "Soils and Society," pre-service elementary teachers explore societal issues where soil is important, develop skills to describe and test soil properties, and create a standards-based Soils and Society Kit that consists of lessons and supporting materials to teach K-8 students about a soil-and-society issue. In "Interactions between Water, Earth's Surface, and Human Activity," students explore the effects of running water on shaping Earth's surface both over geologic time and through short-term flooding events, and produce a brochure to inform citizens of the impact of living near a river. The modules are freely available at http://serc.carleton.edu/integrate/teaching_materials/modules_courses.html and include Instructor Stories, where each author describes how they adapted the module to their teaching environment. The goal of showing different implementations of the materialst is to facilitate adoption and adaption beyond the team of authors.

Benefits of a STEAM Collaboration in Newark, New Jersey: Volcano Simulation through a Glass-Making Experience

ERIC Educational Resources Information Center

Gates, Alexander E.

2017-01-01

A simulated physical model of volcanic processes using a glass art studio greatly enhanced enthusiasm and learning among urban, middle- to high-school aged, largely underrepresented minority students in Newark, New Jersey. The collaboration of a geoscience department with a glass art studio to create a science, technology, engineering, arts, and…

Geoscience is Important? Show Me Why

NASA Astrophysics Data System (ADS)

Boland, M. A.

2017-12-01

"The public" is not homogenous and no single message or form of messaging will connect the entire public with the geosciences. One approach to promoting trust in, and engagement with, the geosciences is to identify specific sectors of the public and then develop interactions and communication products that are immediately relevant to that sector's interests. If the content and delivery are appropriate, this approach empowers people to connect with the geosciences on their own terms and to understand the relevance of the geosciences to their own situation. Federal policy makers are a distinct and influential subgroup of the general public. In preparation for the 2016 presidential election, the American Geosciences Institute (AGI) in collaboration with its 51 member societies prepared Geoscience for America's Critical Needs: Invitation to a National Dialogue, a document that identified major geoscience policy issues that should be addressed in a national policy platform. Following the election, AGI worked with eight other geoscience societies to develop Geoscience Policy Recommendations for the New Administration and the 115th Congress, which outlines specific policy actions to address national issues. State and local decision makers are another important subgroup of the public. AGI has developed online content, factsheets, and case studies with different levels of technical complexity so people can explore societally-relevant geoscience topics at their level of technical proficiency. A related webinar series is attracting a growing worldwide audience from many employment sectors. Partnering with government agencies and other scientific and professional societies has increased the visibility and credibility of these information products with our target audience. Surveys and other feedback show that these products are raising awareness of the geosciences and helping to build reciprocal relationships between geoscientists and decision makers. The core message of all these documents, information products, and events is that geoscience is important, but they frame that message differently to appeal to the direct interests of different audiences.

GeoSearch: A lightweight broking middleware for geospatial resources discovery

NASA Astrophysics Data System (ADS)

Gui, Z.; Yang, C.; Liu, K.; Xia, J.

2012-12-01

With petabytes of geodata, thousands of geospatial web services available over the Internet, it is critical to support geoscience research and applications by finding the best-fit geospatial resources from the massive and heterogeneous resources. Past decades' developments witnessed the operation of many service components to facilitate geospatial resource management and discovery. However, efficient and accurate geospatial resource discovery is still a big challenge due to the following reasons: 1)The entry barriers (also called "learning curves") hinder the usability of discovery services to end users. Different portals and catalogues always adopt various access protocols, metadata formats and GUI styles to organize, present and publish metadata. It is hard for end users to learn all these technical details and differences. 2)The cost for federating heterogeneous services is high. To provide sufficient resources and facilitate data discovery, many registries adopt periodic harvesting mechanism to retrieve metadata from other federated catalogues. These time-consuming processes lead to network and storage burdens, data redundancy, and also the overhead of maintaining data consistency. 3)The heterogeneous semantics issues in data discovery. Since the keyword matching is still the primary search method in many operational discovery services, the search accuracy (precision and recall) is hard to guarantee. Semantic technologies (such as semantic reasoning and similarity evaluation) offer a solution to solve these issues. However, integrating semantic technologies with existing service is challenging due to the expandability limitations on the service frameworks and metadata templates. 4)The capabilities to help users make final selection are inadequate. Most of the existing search portals lack intuitive and diverse information visualization methods and functions (sort, filter) to present, explore and analyze search results. Furthermore, the presentation of the value-added additional information (such as, service quality and user feedback), which conveys important decision supporting information, is missing. To address these issues, we prototyped a distributed search engine, GeoSearch, based on brokering middleware framework to search, integrate and visualize heterogeneous geospatial resources. Specifically, 1) A lightweight discover broker is developed to conduct distributed search. The broker retrieves metadata records for geospatial resources and additional information from dispersed services (portals and catalogues) and other systems on the fly. 2) A quality monitoring and evaluation broker (i.e., QoS Checker) is developed and integrated to provide quality information for geospatial web services. 3) The semantic assisted search and relevance evaluation functions are implemented by loosely interoperating with ESIP Testbed component. 4) Sophisticated information and data visualization functionalities and tools are assembled to improve user experience and assist resource selection.

Identifying Important Career Indicators of Undergraduate Geoscience Students Upon Completion of Their Degree

NASA Astrophysics Data System (ADS)

Wilson, C. E.; Keane, C. M.; Houlton, H. R.

2012-12-01

The American Geosciences Institute (AGI) decided to create the National Geoscience Student Exit Survey in order to identify the initial pathways into the workforce for these graduating students, as well as assess their preparedness for entering the workforce upon graduation. The creation of this survey stemmed from a combination of experiences with the AGI/AGU Survey of Doctorates and discussions at the following Science Education Research Center (SERC) workshops: "Developing Pathways to Strong Programs for the Future", "Strengthening Your Geoscience Program", and "Assessing Geoscience Programs". These events identified distinct gaps in understanding the experiences and perspectives of geoscience students during one of their most profound professional transitions. Therefore, the idea for the survey arose as a way to evaluate how the discipline is preparing and educating students, as well as identifying the students' desired career paths. The discussions at the workshops solidified the need for this survey and created the initial framework for the first pilot of the survey. The purpose of this assessment tool is to evaluate student preparedness for entering the geosciences workforce; identify student decision points for entering geosciences fields and remaining in the geosciences workforce; identify geosciences fields that students pursue in undergraduate and graduate school; collect information on students' expected career trajectories and geosciences professions; identify geosciences career sectors that are hiring new graduates; collect information about salary projections; overall effectiveness of geosciences departments regionally and nationally; demonstrate the value of geosciences degrees to future students, the institutions, and employers; and establish a benchmark to perform longitudinal studies of geosciences graduates to understand their career pathways and impacts of their educational experiences on these decisions. AGI's Student Exit Survey went through a second pilot testing with Spring 2012 graduates from 45 departments across the United States. These graduating students from undergraduate and graduate programs answered questions about their earth science education experiences at the high school, community college, and university levels; their quantitative skills; their research and internship experiences and their immediate plans after graduation. Out of the 294 complete responses to the survey, 233 were from undergraduate students. This presentation will focus on the responses of these undergraduate students. AGI hopes to fully deploy this survey broadly to geosciences departments across the country in Spring 2013. AGI will also begin longitudinally participants from the previous Exit Survey efforts in order to understand their progression through their chosen career paths.

Geoscience Education Opportunities: Partnerships to Advance TeacHing and Scholarship (GEOPATHS) in the Kansas City Metropolitan Area

NASA Astrophysics Data System (ADS)

Niemi, T. M.; Adegoke, J.; Stoddard, E.; Odom, L.; Ketchum, D.

2007-12-01

The GEOPATHS project is a partnership between the University of Missouri Kansas City (UMKC) and the Kansas City Missouri School District (KCMSD). The goal of GEOPATHS is to raise enrollment in the Geosciences, especially among populations that are traditionally underrepresented in the discipline. We are addressing this goal by expanding dual-credit and Advanced Placement (AP) opportunities for high school students and also by serving teachers through enhancing their understanding of geoscience content and inquiry teaching methods using GLOBE resources and protocols. Our focus in the first two years of the project is to increase the number of teachers that are certified to teach AP Environmental Science by offering specially designed professional development workshops for high school teachers in the Kansas City Metropolitan Area. The structure of the workshop for each year is divided into two weeks of content knowledge exploration using the learning cycle and concept mapping, and one week of inquiry-based experiments, field projects, and exercises. We are also supporting teachers in their use of these best-practice methods by providing materials and supplies along with lesson plans for inquiry investigations for their classes. The lesson plans include activities and experiments that are inquiry-based. The last two years of the project will include direct engagement/recruiting of promising minority high school students via paid summer research internships and scholarship offers.

GIS prospectivity mapping and 3D modeling validation for potential uranium deposit targets in Shangnan district, China

NASA Astrophysics Data System (ADS)

Xie, Jiayu; Wang, Gongwen; Sha, Yazhou; Liu, Jiajun; Wen, Botao; Nie, Ming; Zhang, Shuai

2017-04-01

Integrating multi-source geoscience information (such as geology, geophysics, geochemistry, and remote sensing) using GIS mapping is one of the key topics and frontiers in quantitative geosciences for mineral exploration. GIS prospective mapping and three-dimensional (3D) modeling can be used not only to extract exploration criteria and delineate metallogenetic targets but also to provide important information for the quantitative assessment of mineral resources. This paper uses the Shangnan district of Shaanxi province (China) as a case study area. GIS mapping and potential granite-hydrothermal uranium targeting were conducted in the study area combining weights of evidence (WofE) and concentration-area (C-A) fractal methods with multi-source geoscience information. 3D deposit-scale modeling using GOCAD software was performed to validate the shapes and features of the potential targets at the subsurface. The research results show that: (1) the known deposits have potential zones at depth, and the 3D geological models can delineate surface or subsurface ore-forming features, which can be used to analyze the uncertainty of the shape and feature of prospectivity mapping at the subsurface; (2) single geochemistry anomalies or remote sensing anomalies at the surface require combining the depth exploration criteria of geophysics to identify potential targets; and (3) the single or sparse exploration criteria zone with few mineralization spots at the surface has high uncertainty in terms of the exploration target.

Successful recruiting strategies for geoscience degrees and careers at the two-year college: An example from Metropolitan Community College - Kansas City

NASA Astrophysics Data System (ADS)

Wolfe, B.

2012-12-01

The overwhelming majority of students at 2-year colleges take geoscience courses (e.g. physical geology or physical geography) to fulfill part of the general education requirements of the Associates in Arts degree or General Education certificates for transfer to a 4-year school. It is common in community college earth science programs to have a relatively small number of students continuing on to major in geoscience programs at their transfer 4-year institution. To increase interest and retention in geosciences courses, we have developed a two prong approach - one aimed at students looking to transfer to a 4-year institution and the other aimed at students in the often overlooked career and technical education (CTE) programs. In the case of transfer students, we employ a "high touch" approach in introductory Physical Geology courses. This includes raising awareness of geoscience related careers combined with faculty mentor and advisor activities for students who express interest in science on their admission forms or in discussions of potential careers in science in first-year experience courses. Faculty mentorships have been very effective, not only in recruiting students to consider careers in geology, but also in advising a curriculum for students necessary to be successful upon transfer to a 4-year institution (such as completing college level chemistry, physics, and calculus courses prior to transfer). The second approach focuses on students pursuing certificates and degrees in CTE energy-related programs (such as HVAC, industrial engineering technology, electrician, and utility linemen). To increase awareness of vocational related geoscience careers, many of which require a good foundation in the vocational training students are currently pursing, we developed a foundation energy course - Energy and the Environment - which fulfills both the science general education component of the AA degree for students looking to transfer as well as CTE students. The curriculum focuses on fundamental concepts of energy generation and environmental impact, including analysis of energy fundamentals, fossil fuel exploration and use, atmospheric pollution, global climate change, nuclear energy, alternative energy sources, and energy conservation, all of which are directly related to geologic processes. This new course is part of newly created energy certificate programs in Photovoltaics, energy efficiency, and solar thermal - with the intention of expanding to AAS degrees in each.

Enhancing Geoscience Research Discovery Through the Semantic Web

NASA Astrophysics Data System (ADS)

Rowan, Linda R.; Gross, M. Benjamin; Mayernik, Matthew; Khan, Huda; Boler, Frances; Maull, Keith; Stott, Don; Williams, Steve; Corson-Rikert, Jon; Johns, Erica M.; Daniels, Michael; Krafft, Dean B.; Meertens, Charles

2016-04-01

UNAVCO, UCAR, and Cornell University are working together to leverage semantic web technologies to enable discovery of people, datasets, publications and other research products, as well as the connections between them. The EarthCollab project, a U.S. National Science Foundation EarthCube Building Block, is enhancing an existing open-source semantic web application, VIVO, to enhance connectivity across distributed networks of researchers and resources related to the following two geoscience-based communities: (1) the Bering Sea Project, an interdisciplinary field program whose data archive is hosted by NCAR's Earth Observing Laboratory (EOL), and (2) UNAVCO, a geodetic facility and consortium that supports diverse research projects informed by geodesy. People, publications, datasets and grant information have been mapped to an extended version of the VIVO-ISF ontology and ingested into VIVO's database. Much of the VIVO ontology was built for the life sciences, so we have added some components of existing geoscience-based ontologies and a few terms from a local ontology that we created. The UNAVCO VIVO instance, connect.unavco.org, utilizes persistent identifiers whenever possible; for example using ORCIDs for people, publication DOIs, data DOIs and unique NSF grant numbers. Data is ingested using a custom set of scripts that include the ability to perform basic automated and curated disambiguation. VIVO can display a page for every object ingested, including connections to other objects in the VIVO database. A dataset page, for example, includes the dataset type, time interval, DOI, related publications, and authors. The dataset type field provides a connection to all other datasets of the same type. The author's page shows, among other information, related datasets and co-authors. Information previously spread across several unconnected databases is now stored in a single location. In addition to VIVO's default display, the new database can be queried using SPARQL, a query language for semantic data. EarthCollab is extending the VIVO web application. One such extension is the ability to cross-link separate VIVO instances across institutions, allowing local display of externally curated information. For example, Cornell's VIVO faculty pages will display UNAVCO's dataset information and UNAVCO's VIVO will display Cornell faculty member contact and position information. About half of UNAVCO's membership is international and we hope to connect our data to institutions in other countries with a similar approach. Additional extensions, including enhanced geospatial capabilities, will be developed based on task-centered usability testing.

AMS Online Weather Studies: The National Dissemination of a Distance Learning Course for Enhancing Diversity in the Geosciences

NASA Astrophysics Data System (ADS)

Weinbeck, R. S.; Geer, I. W.; Mills, E. W.; Porter, W. A.; Moran, J. M.

2004-12-01

Our nation faces a serious challenge in attracting young people to science and science-related careers (including teaching). This is particularly true for members of groups underrepresented in science, mathematics, engineering, and technology and is especially acute in the number of minority college students majoring in the geosciences. A formidable obstacle in attracting undergraduates to the geosciences is lack of access, that is, no opportunity to enroll in geoscience courses simply because none is offered at their college or university. Often college-level introductory courses are a student's first exposure to the geosciences. To help alleviate this problem of access, the American Meteorological Society (AMS) has developed and implemented nationally an introductory weather and climate course, Online Weather Studies, which can be added to an institution's menu of general education course offerings. This highly successful course has been licensed by over 230 colleges and universities nationwide, among them 72 minority-serving institutions which have joined via the AMS Online Weather Studies Geosciences Diversity Program since 2002. This program designed to reach institutions serving large numbers of minority students has been made possible through support from the National Science Foundation (NSF) Opportunities for Enhancing Diversity in the Geosciences (OEDG) and Course, Curriculum and Laboratory Improvement-National Dissemination (CCLI-ND) programs. Online Weather Studies is an innovative, 12- to 15-week introductory college-level, online distance-learning course on the fundamentals of atmospheric science. Learner-formatted current weather data are delivered via the Internet and coordinated with investigations keyed to the day's weather. The principal innovation of Online Weather Studies is that students learn about weather as it happens in near real-time - a highly motivational learning experience. The AMS Education Program designed and services this course and makes it available to colleges and universities as a user-friendly turnkey package with electronic and printed components. The AMS Geosciences Diversity Program, in cooperation with the National Weather Service (NWS), facilitates institutional participation in Online Weather Studies. Prior to an instructor's initial offering of the course, he or she is invited to attend a one-week course implementation workshop at the NWS Training Center at Kansas City, MO. Participants are encouraged to share best practices ideas in science content and teaching strategies related to their offering of Online Weather Studies. Through the course homepage, students are provided with information on further studies in the atmospheric sciences, opportunities for internships and summer research, and career counseling. Meteorologists-in-Charge at NWS Weather Forecast Offices across the nation have interacted with minority-serving institutions to encourage adoption of the AMS weather course. Also, participating faculty members are invited to the Educational Symposium of the AMS Annual Meeting where they will attend a special Diversity Session and are encouraged to present posters.

The evolving role of data scientist during 20 years of the British Atmospheric Data Centre (Invited)

NASA Astrophysics Data System (ADS)

Pascoe, S.; Parton, G.; Pascoe, C.; Guillory, A.; da Costa, E. D.

2013-12-01

In 2014 The British Atmospheric Data Centre (BADC), now part of the Centre of Environmental Data Archival (CEDA), will celebrate its 20th anniversary. During its lifetime, most BADC staff have defined themselves as data scientists by virtue of being scientists by background and "data workers" by practice. However, the definition of data scientist has been ill defined until recently. As the term has become popularised in the world of business and general information technology, we ask ourselves to what extent the popular definition fits our profession. We observe that data science, as practised at CEDA, encompasses several roles which overlap and compliment each other as we strive to be enablers of data exploitation. For us a data scientist's skills include elements of data curation, software engineering, data infrastructure management and data-intensive research. As data science has evolved the balance between these roles has shifted in response to changes in technology, demands of the research community and funding drivers. We have had to balance our role as enablers of data exploitation, by providing services and infrastructure to the geo-science community, with our role as pioneers of data exploitation itself. By telling the story of how these roles have evolved during the 20 year history of the BADC, we aim to explore the maturing role of data scientist as practised within the geo-sciences and contrast that role with its recently popularised usage. Looking forward we will address questions about how centres of expertise, such as CEDA, can best increase the data capabilities of geo-science research as a whole in order to facilitate the transition to data-intensive science.

Geoscience research databases for coastal Alabama ecosystem management

USGS Publications Warehouse

Hummell, Richard L.

1995-01-01

Effective management of complex coastal ecosystems necessitates access to scientific knowledge that can be acquired through a multidisciplinary approach involving Federal and State scientists that take advantage of agency expertise and resources for the benefit of all participants working toward a set of common research and management goals. Cooperative geostatic investigations have led toward building databases of fundamental scientific knowledge that can be utilized to manage coastal Alabama's natural and future development. These databases have been used to assess the occurrence and economic potential of hard mineral resources in the Alabama EFZ, and to support oil spill contingency planning and environmental analysis for coastal Alabama.

Copper-silver deposits of the Revett Formation, Montana and Idaho: origin and resource potential

USGS Publications Warehouse

Frost, Thomas P.; Zientek, Michael L.

2006-01-01

The Revett Formation of northern Idaho and western Montana contains major stratabound copper-silver deposits near Troy, Rock Creek, and Rock Lake, Montana. To help the U.S. Forest Service (USFS) meet its goal of integrating geoscience information into the land-planning process, U.S. Geological Survey (USGS) scientists recently completed a compilation of regional stratigraphy and mineralogy of the Revett Formation and a mineral resource assessment of Revett-type copper-silver deposits. The USGS assessment indicates that a large area of USFS-administered land in northwestern Montana and northern Idaho may contain significant undiscovered Revett-type copper-silver deposits.

Développement durable à l'échelle de la planète et gestion des ressources en eau et en solsSustainable development on a global scale and management of water and soil resources

NASA Astrophysics Data System (ADS)

Petit, Michel

2003-06-01

Despite some controversies, an international consensus on what is sustainable development has emerged, the nature of which is first specified. Then the author explains why the implementation of the measures consistent with this consensus comes up against obstacles, particularly political ones, which makes clear why the topic is still under animated debate. Examples will be taken in the domain of the management of water and soils resources. To cite this article: M. Petit, C. R. Geoscience 335 (2003).

Developing Strong Geoscience Programs and Departments

NASA Astrophysics Data System (ADS)

MacDonald, R.; Manduca, C. A.

2002-12-01

Strong geoscience programs are essential for preparing future geoscientists and developing a broad public understanding of our science. Faculty working as a department team can create stronger programs than individual faculty working alone. Workshops sponsored by Project Kaleidoscope (www.pkal.org) on departmental planning in the geosciences have emphasized the importance of designing programs in the context of both departmental and student goals. Well-articulated goals form a foundation for designing curriculum, courses, and other departmental activities. Course/skill matrices have emerged as particularly valuable tools for analyzing how individual courses combine in a curriculum to meet learning goals. Integrated programs where students have opportunities to learn and use skills in multiple contexts have been developed at several institutions. Departments are leveraging synergies between courses to more effectively reach departmental goals and capitalize on opportunities in the larger campus environment. A full departmental program extends beyond courses and curriculum. Studies in physics (National Task Force on Undergraduate Physics, Hilborne, 2002) indicate the importance of activities such as recruiting able students, mentoring students, providing courses appropriate for pre-service K-12 teachers, assisting with professional development for a diversity of careers, providing opportunities for undergraduates to participate in research, and making connections with the local industries and businesses that employ graduates. PKAL workshop participants have articulated a wide variety of approaches to undergraduate research opportunities within and outside of class based on their departmental goals, faculty goals, and resources. Similarly, departments have a wide variety of strategies for developing productive synergies with campus-wide programs including those emphasizing writing skills, quantitative skills, and environmental studies. Mentoring and advising activities are becoming more central to many departmental programs and can effectively draw on campus, alumni, and industry resources. Attention to the role and reputation of the department on campus is important in creating a supportive climate for departmental activities. The challenges of creating a strong program can be most effectively met using a team approach that capitalizes on the strengths of every department member.

OneGeology - Access to geoscience for all

NASA Astrophysics Data System (ADS)

Komac, Marko; Lee, Kathryn; Robida, Francois

2014-05-01

OneGeology is an initiative of Geological Survey Organisations (GSO) around the globe that dates back to Brighton, UK in 2007. Since then OneGeology has been a leader in developing geological online map data using a new international standard - a geological exchange language known as 'GeoSciML'. Increased use of this new language allows geological data to be shared and integrated across the planet with other organisations. One of very important goals of OneGeology was a transfer of valuable know-how to the developing world, hence shortening the digital learning curve. In autumn 2013 OneGeology was transformed into a Consortium with a clearly defined governance structure, making its structure more official, its operability more flexible and its membership more open where in addition to GSO also to other type of organisations that manage geoscientific data can join and contribute. The next stage of the OneGeology initiative will hence be focused into increasing the openness and richness of that data from individual countries to create a multi-thematic global geological data resource on the rocks beneath our feet. Authoritative information on hazards and minerals will help to prevent natural disasters, explore for resources (water, minerals and energy) and identify risks to human health on a planetary scale. With this new stage also renewed OneGeology objectives were defined and these are 1) to be the provider of geoscience data globally, 2) to ensure exchange of know-how and skills so all can participate, and 3) to use the global profile of 1G to increase awareness of the geosciences and their relevance among professional and general public. We live in a digital world that enables prompt access to vast amounts of open access data. Understanding our world, the geology beneath our feet and environmental challenges related to geology calls for accessibility of geoscientific data and OneGeology Portal (portal.onegeology.org) is the place to find them.

Entering a New ERA: Education Resources and AGU

NASA Astrophysics Data System (ADS)

Karsten, J. L.; Johnson, R. M.

2001-12-01

Professional societies play a unique role in the on-going battle to improve public education in the Earth and space sciences. With guidance from its Committee on Education and Human Resources (CEHR), AGU has traditionally sponsored strong programs that provide mechanisms for linking its research membership with the formal/informal science education communities. Among the most successful of these are tutorials for K-12 teachers taught by AGU members during national meetings (e.g., GIFT - Geophysical Information For Teachers) and internships that allow teachers to experience geophysical science research first-hand (e.g., STaRS - Science Teacher and Research Scientist). AGU also co-sponsors major symposia to discuss and develop strategies for Earth science education reform (e.g., the NSF-sponsored Shaping the Future workshop) and provides an annual forum for the Heads and Chairs of undergraduate geoscience departments to discuss common problems and share solutions. In the fall of 2001, AGU expects to unveil a major new education and outreach website that will provide enhanced opportunities for communicating to students, teachers and the public about AGU members' research and new directions in geophysical science education. The most important contribution that AGU makes, however, is to validate and prominently endorse the education and outreach efforts of its members, both by sponsoring well-attended, education-related special sessions at AGU national meetings and by annually honoring individuals or groups with the Excellence in Geoscience Education award. Recent staff changes at AGU headquarters have brought new opportunities to expand upon these successful existing programs and move in other directions that capitalize on the strengths of the organization. Among new initiatives being considered are programs that partner education efforts with those being developed as part of several large research programs, curriculum modules that will promote teaching earth sciences-related materials within core physics, chemistry, and math curricula, and more sophisticated informal science education programs. Efforts to better coordinate AGU's education programs with those being developed by other professional geoscience organizations are also underway.

GeoMapApp, Virtual Ocean, and other Free Data Resources for the 21st Century Classroom

NASA Astrophysics Data System (ADS)

Goodwillie, A. M.; Ryan, W.; Carbotte, S.; Melkonian, A.; Coplan, J.; Arko, R.; Ferrini, V.; O'Hara, S.; Leung, A.; Bonckzowski, J.

2008-12-01

With funding from the U.S. National Science Foundation, the Marine Geoscience Data System (MGDS) (http://www.marine-geo.org/) is developing GeoMapApp (http://www.geomapapp.org) - a computer application that provides wide-ranging map-based visualization and manipulation options for interdisciplinary geosciences research and education. The novelty comes from the use of this visual tool to discover and explore data, with seamless links to further discovery using traditional text-based approaches. Users can generate custom maps and grids and import their own data sets. Built-in functionality allows users to readily explore a broad suite of interactive data sets and interfaces. Examples include multi-resolution global digital models of topography, gravity, sediment thickness, and crustal ages; rock, fluid, biology and sediment sample information; research cruise underway geophysical and multibeam data; earthquake events; submersible dive photos of hydrothermal vents; geochemical analyses; DSDP/ODP core logs; seismic reflection profiles; contouring, shading, profiling of grids; and many more. On-line audio-visual tutorials lead users step-by-step through GeoMapApp functionality (http://www.geomapapp.org/tutorials/). Virtual Ocean (http://www.virtualocean.org/) integrates GeoMapApp with a 3-D earth browser based upon NASA WorldWind, providing yet more powerful capabilities. The searchable MGDS Media Bank (http://media.marine-geo.org/) supports viewing of remarkable images and video from the NSF Ridge 2000 and MARGINS programs. For users familiar with Google Earth (tm), KML files are available for viewing several MGDS data sets (http://www.marine-geo.org/education/kmls.php). Examples of accessing and manipulating a range of geoscience data sets from various NSF-funded programs will be shown. GeoMapApp, Virtual Ocean, the MGDS Media Bank and KML files are free MGDS data resources and work on any type of computer. They are currently used by educators, researchers, school teachers and the general public.

Building Strong Geoscience Departments: Case Studies and Findings from Six Years of Programming

NASA Astrophysics Data System (ADS)

Iverson, E. A.; Lee, S.; Ormand, C. J.; Feiss, P. G.; Macdonald, H.; Manduca, C. A.; Richardson, R. M.

2011-12-01

Begun in 2005, the Building Strong Geoscience Departments project sought to help geoscience departments respond to changes in geosciences research, academic pressures, and the changing face of the geosciences workforce by working as a team, planning strategically, and learning from the experiences of other geoscience departments. Key strategies included becoming more central to their institution's mission and goals; articulating the department's learning goals for students; designing coordinated curricula, co-curricular activities, and assessments to meet these goals; and recruiting students effectively. A series of topical workshops identified effective practices in use in the U.S. and Canada. These practices were documented on the project website and disseminated through a national workshop for teams of faculty, through activities at the AGU Heads and Chairs workshops, and in a visiting workshop program bringing leaders to campuses. The program has now involved over 450 participants from 185 departments. To understand the impact of the program, we engaged in ongoing discussion with five departments of various sizes and institutional types, and facing a variety of immediate challenges. In aggregate they made use of the full spectrum of project offerings. These departments all reported that the project brought an important new perspective to their ability to work as a department: they have a better understanding of how their departments' issues relate to the national scene, have more strategies for making the case for the entire department to college administrators, and are better poised to make use of campus resources including the external review process. These results were consistent with findings from end-of-workshop surveys. Further they developed the ability to work together as a team to address departmental challenges through collective problem solving. As a result of their workshop participation, two of the departments who considered their department to be vulnerable to elimination believe they are in a better position to survive and thrive. All five departments reported changes to their curriculum that addressed goals such as attracting more majors, recruiting students from underrepresented groups and integrating initiatives such as service learning. Three departments reported making strides to increase their visibility by implementing new community activities, involving alumni, and using social networking. Two departments became more intentional in collecting data for assessment/external review. As one department member shared, they learned that it was not enough to just teach and to do good research, they became their own advocates for change and believe it made a significant difference in their success on campus.

Meeting the Challenges for Gender Diversity in the Geosciences

NASA Astrophysics Data System (ADS)

Bell, R. E.; Cane, M. A.; Kastens, K. A.; Miller, R. B.; Mutter, J. C.; Pfirman, S. L.

2003-12-01

Women are now routinely chief scientists on major cruises, lead field parties to all continents, and have risen to leadership positions in professional organizations, academic departments and government agencies including major funding agencies. They teach at all levels, advise research students, make research discoveries and receive honors in recognition of their achievements. Despite these advances, women continue to be under-represented in the earth, ocean, and atmospheric sciences. As of 1997 women received only 29% of the doctorates in the earth, atmospheric, and oceanographic sciences and accounted for only 13% of employed Ph.D.s in these fields. Women's salaries also lag: the median annual salary for all Ph.D. geoscientists was \\60,000; for women the figure is \\47,000. Solving the problem of gender imbalance in the geosciences requires understanding of the particular obstacles women face in our field. The problem of under-representation of women requires that earth science departments, universities and research centers, funding agencies, and professional organizations like AGU take constructive action to recognize the root causes of the evident imbalance, and enact corrective policies. We have identified opportunities and challenges for each of these groups. A systematic study of the flux of women at Columbia University enabled a targeted strategy towards improving gender diversity based on the observed trends. The challenge for academic institutions is to document the flux of scientists and develop an appropriate strategy to balance the geoscience demographics. Based on the MIT study, an additional challenge faces universities and research centers. To enhance gender diversity these institutions need to develop transparency in promotion processes and open distribution of institutional resources. The challenge for granting agencies is to implement policies that ease the burden of extensive fieldwork on parents. Many fields of science require long work hours but the geosciences are unique in their requirement of extended fieldwork in remote locations, which raises issues for parents, and may be one reason geosciences lags behind other science disciplines in gender diversity. AGU and AGI have both conducted comprehensive and important studies on the status of women in science at all levels. Conducting flux studies and identifying the decision points in the advancement of scientists will provide fundamental data for designing successful programs to enhance diversity in the geosciences. Professional organizations such as AGU and the Geological Society of America should develop projects to monitor the career patterns of scientists, both men and women, beyond graduate school and the first job.

Success of the International Year of the Planet Earth through Targeted High-impact Programs at the American Geological Institute

NASA Astrophysics Data System (ADS)

Leahy, P.

2007-12-01

The American Geological Institute (AGI) is one of the 12 founding partners of the International Year of the Planet Earth (IYPE) and as such AGI serves on its governing board. AGI is a nonprofit federation of 44 geoscientific and professional associations that represents more than 120,000 geologists, geophysicists, and other earth scientists. AGI provides information services to geoscientists, serves as a voice of shared interests in our profession, plays a major role in strengthening geoscience education, and strives to increase public awareness of the vital role the geosciences play in society's use of resources, resilience to natural hazards, and the health of the environment. The outreach and educational opportunities afforded by IYPE provide AGI with an international venue to promote the role of the geosciences in the daily life of society. AGI's successful release of the 4-part television series entitled Faces of Earth done in partnership with the Discovery Communications is a hallmark example of an outreach product that is technically accurate but designed to engage the non-scientific audience in the wonderment of our science. The series focuses on building the planet, shaping the planet, assembling America, and the human world. Custom short cuts have been produced for special purposes and one of these may be used as part of an IYPE-launch event in Europe. AGI's news magazine, Geotimes will highlight appropriate IYPE events to increase the awareness of the American geoscience community. In addition, Geotimes will promote IYPE by using its logo routinely and through publishing advertisements reminding its professional and public readership of the importance of the IYPE triennium. Similarly, as part of AGI's K-12 educational efforts and teacher training and through its development of Earth Science Week materials, the goals, accomplishments, and importance of IYPE will be incorporated into the targeted educational audiences. IYPE activities will be highlighted on the 2007 Earth Science Week web site, and AGI staff is participating as "first bloggers" for the IYPE Earthlearningidea online investigations. A major AGI contribution to IYPE will be an assessment of the geoscience workforce in the United States. This effort will involve analyzing supply and demand statistics for workforce and working with academia to provide material aimed at ensuring both an adequate and high-quality supply of geoscientists for the future. Such an assessment can be used in collaboratively building a global assessment of the geoscience profession.

Facilitating career advancement for women in the Geosciences through the Earth Science Women's Network (ESWN)

NASA Astrophysics Data System (ADS)

Hastings, M. G.; Kontak, R.; Holloway, T.; Kogan, M.; Laursen, S. L.; Marin-Spiotta, E.; Steiner, A. L.; Wiedinmyer, C.

2011-12-01

The Earth Science Women's Network (ESWN) is a network of women geoscientists, many of who are in the early stages of their careers. The mission of ESWN is to promote career development, build community, provide informal mentoring and support, and facilitate professional collaborations, all towards making women successful in their scientific careers. ESWN currently connects over 1000 women across the globe, and includes graduate students, postdoctoral associates, faculty from a diversity of colleges and universities, program managers, and government, non-government and industry researchers. ESWN facilitates communication between its members via an email listserv and in-person networking events, and also provides resources to the broader community through the public Earth Science Jobs Listserv that hosts over 1800 subscribers. With funding from a NSF ADVANCE PAID grant, our primary goals include growing our membership to serve a wider section of the geosciences community, designing and administering career development workshops, promoting professional networking at major scientific conferences, and developing web resources to build connections, collaborations, and peer mentoring for and among women in the Earth Sciences. Recognizing that women in particular face a number of direct and indirect biases while navigating their careers, we aim to provide a range of opportunities for professional development that emphasize different skills at different stages of career. For example, ESWN-hosted mini-workshops at national scientific conferences have targeted skill building for early career researchers (e.g., postdocs, tenure-track faculty), with a recent focus on raising extramural research funding and best practices for publishing in the geosciences literature. More concentrated, multi-day professional development workshops are offered annually with varying themes such as Defining Your Research Identity and Building Leadership Skills for Success in Scientific Organizations. These workshops bring together a variety of women with the goals of identifying personal strengths, defining career goals, building a network of contacts, and supporting actions to achieve personal and career success. ESWN members have identified increasing their professional networks as one of the most important needs for advancing their careers. As part of ESWN, members have reported gains in a number of aspects of their personal and professional lives including: knowledge about career resources; a greater understanding of the challenges facing women in science and resources to overcome them; a sense of community and therefore less isolation; greater confidence in their own career trajectories; professional collaborations; emotional support on a variety of issues; and greater engagement and retention in scientific careers.

Teachers' Geoscience Career Knowledge and Implications for Enhancing Diversity in the Geosciences

ERIC Educational Resources Information Center

Sherman-Morris, Kathleen; Brown, Michael E.; Dyer, Jamie L.; McNeal, Karen S.; Rodgers, John C., III

2013-01-01

This study examines discrepancies between geoscience career knowledge and biology career knowledge among Mississippi science teachers. Principals and in-service teachers were also surveyed about their perception of geoscience careers and majors. Scores were higher for knowledge of what biologists do (at work) than about what geoscientists do.…

Myths in funding ocean research at the National Science Foundation

NASA Astrophysics Data System (ADS)

Duce, Robert A.; Benoit-Bird, Kelly J.; Ortiz, Joseph; Woodgate, Rebecca A.; Bontempi, Paula; Delaney, Margaret; Gaines, Steven D.; Harper, Scott; Jones, Brandon; White, Lisa D.

2012-12-01

Every 3 years the U.S. National Science Foundation (NSF), through its Advisory Committee on Geosciences, forms a Committee of Visitors (COV) to review different aspects of the Directorate for Geosciences (GEO). This year a COV was formed to review the Biological Oceanography (BO), Chemical Oceanography (CO), and Physical Oceanography (PO) programs in the Ocean Section; the Marine Geology and Geophysics (MGG) and Integrated Ocean Drilling Program (IODP) science programs in the Marine Geosciences Section; and the Ocean Education and Ocean Technology and Interdisciplinary Coordination (OTIC) programs in the Integrative Programs Section of the Ocean Sciences Division (OCE). The 2012 COV assessed the proposal review process for fiscal year (FY) 2009-2011, when 3843 proposal actions were considered, resulting in 1141 awards. To do this, COV evaluated the documents associated with 206 projects that were randomly selected from the following categories: low-rated proposals that were funded, high-rated proposals that were funded, low-rated proposals that were declined, high-rated proposals that were declined, some in the middle (53 awarded, 106 declined), and all (47) proposals submitted to the Rapid Response Research (RAPID) funding mechanism. NSF provided additional data as requested by the COV in the form of graphs and tables. The full COV report, including graphs and tables, is available at http://www.nsf.gov/geo/acgeo_cov.jsp.

The Moon: Resources, Future Development and Colonization

NASA Astrophysics Data System (ADS)

Schrunk, David; Sharpe, Burton; Cooper, Bonnie; Thangavelu, Madhu

1999-07-01

This unique, visionary and innovative book describes how the Moon could be colonised and developed as a platform for science, industrialization and exploration of our Solar System and beyond. Thirty years ago, the world waited with baited breath to watch history in the making, as man finally stepped onto the moon's surface. In the last few years, there has been growing interest in the idea of a return to the moon. This book describes the reasons why we should now start lunar development and settlement, and how this goal may be accomplished. The authors, all of whom are hugely experienced space scientists, consider the rationale and steps necessary for establishing permanent bases on the Moon. Their innovative and scientific-based analysis concludes that the Moon has sufficient resources for large-scale human development. Their case for development includes arguments for a solar-powered electric grid and railroad, creation of a utilities infrastructure, habitable facilities, scientific operations and the involvement of private enterprise with the public sector in the macroproject. By transferring and adapting existing technologies to the lunar environment, the authors argue that it will be possible to use lunar resources and solar power to build a global lunar infrastructure embracing power, communication, transportation, and manufacturing. This will support the migration of increasing numbers of people from Earth, and realization of the Moon's scientific potential. As an inhabited world, the Moon is an ideal site for scientific laboratories dedicated to geosciences, astronomy and life sciences, and most importantly, it would fulfil a role as a proving ground and launch pad for future Solar System exploration. The ten chapters in this book go beyond the theoretical and conceptual. With vision and foresight, the authors offer practical means for establishing permanent bases on the Moon. The book will make fascinating and stimulating reading for students in astronautics, space science, life sciences, space engineering and technology as well as professional space scientists, engineers and technologists in space projects.

New Catalog of Resources Enables Paleogeosciences Research

NASA Astrophysics Data System (ADS)

Lingo, R. C.; Horlick, K. A.; Anderson, D. M.

2014-12-01

The 21st century promises a new era for scientists of all disciplines, the age where cyber infrastructure enables research and education and fuels discovery. EarthCube is a working community of over 2,500 scientists and students of many Earth Science disciplines who are looking to build bridges between disciplines. The EarthCube initiative will create a digital infrastructure that connects databases, software, and repositories. A catalog of resources (databases, software, repositories) has been produced by the Research Coordination Network for Paleogeosciences to improve the discoverability of resources. The Catalog is currently made available within the larger-scope CINERGI geosciences portal (http://hydro10.sdsc.edu/geoportal/catalog/main/home.page). Other distribution points and web services are planned, using linked data, content services for the web, and XML descriptions that can be harvested using metadata protocols. The databases provide searchable interfaces to find data sets that would otherwise remain dark data, hidden in drawers and on personal computers. The software will be described in catalog entries so just one click will lead users to methods and analytical tools that many geoscientists were unaware of. The repositories listed in the Paleogeosciences Catalog contain physical samples found all across the globe, from natural history museums to the basements of university buildings. EarthCube has over 250 databases, 300 software systems, and 200 repositories which will grow in the coming year. When completed, geoscientists across the world will be connected into a productive workflow for managing, sharing, and exploring geoscience data and information that expedites collaboration and innovation within the paleogeosciences, potentially bringing about new interdisciplinary discoveries.

Pathways to the Geosciences through 2YR Community Colleges: A Strategic Recruitment Approach being used at Texas A&M University

NASA Astrophysics Data System (ADS)

Houser, C.; Nunez, J.; Miller, K. C.

2016-12-01

Department and college operating budgets are increasingly tide to enrollment and student credit hour production, which requires geoscience programs to develop strategic recruitment programs to ensure long-term stability, but also to increase institutional support. There is evidence that proactive high school recruitment programs are successful in engaging students in the geosciences, particularly those that involve the parents, but these programs typically have relatively low-yields and are relatively expensive. This means that increased enrollment of undergraduates in geosciences programs and participation by under-represented groups depends on innovative and effective recruitment and retention practices. The College of Geosciences at Texas A&M University has recently developed a Pathways to the Geosciences program that facilitates the transfer of students from 2-year institutions by providing direction to students interested in the geosciences from one of our partner institutions: Blinn College, Lee College, Houston Community College, San Jacinto College and Lone Star College. Each of the partner institutions offer disciplinary majors related to the geosciences, providing a gateway for students to discover and consider the geosciences starting in their freshman year. The guided pathways provide much needed direction without restricting options and allow students to see connections between courses and their career goals. In its first year, the Pathways to the Geosciences program has resulted in a significant increase in transfer applications and admissions from the partner institutions by 74% and 107% respectively. The program has been successful because we have been proactive in helping students at the partner institutions find the information they need to effectively transfer to a 4-year program. The increase in applications is evidence that students from our partner institutions are being intentional in following a pathway to a major in the College of Geosciences.

High Demand, Core Geosciences, and Meeting the Challenges through Online Approaches

NASA Astrophysics Data System (ADS)

Keane, Christopher; Leahy, P. Patrick; Houlton, Heather; Wilson, Carolyn

2014-05-01

As the geosciences has evolved over the last several decades, so too has undergraduate geoscience education, both from a standpoint of curriculum and educational experience. In the United States, we have been experiencing very strong growth in enrollments in geoscience, as well as employment demand for the last 7 years. That growth has been largely fueled by all aspects of the energy boom in the US, both from the energy production side and the environmental management side. Interestingly the portfolio of experiences and knowledge required are strongly congruent as evidenced from results of the American Geosciences Institute's National Geoscience Exit Survey. Likewise, the demand for new geoscientists in the US is outstripping even the nearly unprecedented growth in enrollments and degrees, which is calling into question the geosciences' inability to effectively reach into the largest growing segments of the U.S. College population - underrepresented minorities. We will also examine the results of the AGI Survey on Geoscience Online Learning and examine how the results of that survey are rectified with Peter Smith's "Middle Third" theory on "wasted talent" because of spatial, economic, and social dislocation. In particular, the geosciences are late to the online learning game in the United States and most faculty engaged in such activities are "lone wolves" in their department operating with little knowledge of the support structures that exist in such development. Yet the most cited barriers for faculty not engaging actively in online learning is the assertion that laboratory and field experiences will be lost and thus fight engaging in this medium. However, the survey shows that faculty are discovering novel approaches to address these issues, many of which have great application to enabling geoscience programs in the United States to meet the expanding demand for geoscience degrees.

Improving Undergraduate STEM Education: Pathways into Geoscience (IUSE: GEOPATHS) - A National Science Foundation Initiative

NASA Astrophysics Data System (ADS)

Jones, B.; Patino, L. C.

2016-12-01

Preparation of the future professional geoscience workforce includes increasing numbers as well as providing adequate education, exposure and training for undergraduates once they enter geoscience pathways. It is important to consider potential career trajectories for geoscience students, as these inform the types of education and skill-learning required. Recent reports have highlighted that critical thinking and problem-solving skills, spatial and temporal abilities, strong quantitative skills, and the ability to work in teams are among the priorities for many geoscience work environments. The increasing focus of geoscience work on societal issues (e.g., climate change impacts) opens the door to engaging a diverse population of students. In light of this, one challenge is to find effective strategies for "opening the world of possibilities" in the geosciences for these students and supporting them at the critical junctures where they might choose an alternative pathway to geosciences or otherwise leave altogether. To address these and related matters, The National Science Foundation's (NSF) Directorate for Geosciences (GEO) has supported two rounds of the IUSE: GEOPATHS Program, to create and support innovative and inclusive projects to build the future geoscience workforce. This program is one component in NSF's Improving Undergraduate STEM Education (IUSE) initiative, which is a comprehensive, Foundation-wide effort to accelerate the quality and effectiveness of the education of undergraduates in all of the STEM fields. The two tracks of IUSE: GEOPATHS (EXTRA and IMPACT) seek to broaden and strengthen connections and activities that will engage and retain undergraduate students in geoscience education and career pathways, and help prepare them for a variety of careers. The long-term goal of this program is to dramatically increase the number and diversity of students earning undergraduate degrees or enrolling in graduate programs in geoscience fields, as well as ensure that they have the necessary skills and competencies to succeed as next generation professionals in a variety of employment sectors.

Bridging the Geoscientist Workforce Gap: Advanced High School Geoscience Programs

NASA Astrophysics Data System (ADS)

Schmidt, Richard William

The purpose of this participatory action research was to create a comprehensive evaluation of advanced geoscience education in Pennsylvania public high schools and to ascertain the possible impact of this trend on student perceptions and attitudes towards the geosciences as a legitimate academic subject and possible career option. The study builds on an earlier examination of student perceptions conducted at Northern Arizona University in 2008 and 2009 but shifts the focus to high school students, a demographic not explored before in this context. The study consisted of three phases each examining a different facet of the advanced geoscience education issue. Phase 1 examined 572 public high schools in 500 school districts across Pennsylvania and evaluated the health of the state's advanced geoscience education through the use of an online survey instrument where districts identified the nature of their geoscience programs (if any). Phase 2 targeted two groups of students at one suburban Philadelphia high school with an established advanced geoscience courses and compared the attitudes and perceptions of those who had been exposed to the curricula to a similar group of students who had not. Descriptive and statistically significant trends were then identified in order to assess the impact of an advanced geoscience education. Phase 3 of the study qualitatively explored the particular attitudes and perceptions of a random sampling of the advanced geoscience study group through the use of one-on-one interviews that looked for more in-depth patterns of priorities and values when students considered such topics as course enrollment, career selection and educational priorities. The results of the study revealed that advanced geoscience coursework was available to only 8% of the state's 548,000 students, a percentage significantly below that of the other typical K-12 science fields. It also exposed several statistically significant differences between the perceptions and attitudes of the two student research groups that could be contributing to the developing geoscience workforce crisis. However, the study also validated the notion that, in spite of significant blocking forces arrayed in front of them, advanced geoscience programs can be successful and offer viable curricula that serve to increase students' interest and opinions towards the field. By not only recognizing the existence of the geoscience workforce gap but also understanding its root causes, the role of advanced high school geoscience education emerges as an integral part of a solution to the problem.

Commonwealth of Independent States aerospace science and technology, 1992: A bibliography with indexes

NASA Technical Reports Server (NTRS)

1993-01-01

This bibliography contains 1237 annotated references to reports and journal articles of Commonwealth of Independent States (CIS) intellectual origin entered into the NASA Scientific and Technical Information System during 1992. Representative subject areas include the following: aeronautics, astronautics, chemistry and materials, engineering, geosciences, life sciences, mathematical and computer sciences, physics, social sciences, and space sciences.

The Geoscience Ambassador: Training opportunities and skill development for tomorrow's geoscientists

NASA Astrophysics Data System (ADS)

Price, Louise

2017-04-01

How can high schools geoscience teachers engage younger students who are not taught geoscience subjects at lower key stages? As passionate practitioners of learning, high school teachers are in a seemingly ideal position to inspire young learners to study and pursue a career in the field of geoscience. However, recruitment of students is often challenging if students do not have the opportunity to study the subjects first. For geoscience subjects such as geology to remain sustainable and viable at A-level, it is imperative that high schools invest time and effort in improving student awareness of subjects which students can access later in their academic career. Perhaps one of the greatest, most accessible and overlooked promotional tools for a geoscience subject are the students themselves. In 2016/2017, a new scheme at Hessle High School and Sixth Form in Yorkshire, United Kingdom, offered senior A-level geology students the opportunity to become "Geoscience Ambassadors". These students were recruited to act as champions for their geoscience subject (geology) to support with inspiring and engaging younger students who may otherwise not choose the subject. The traditional method of disseminating learning is to offer "train the trainer" sessions where training is delivered to peers for onward cascaded teaching and education. On returning from the 2016 Geosciences Information for Teachers (GIFT) workshop at EGU, training was provided to other teaching professionals on the activities and key learning points, the training was also disseminated to an enthusiastic group of A-level students to enable them to become Geoscience Ambassadors. This cascade approach moves away from the tradition of training high school staff alone on new pedagogies but additionally trains young and enthusiastic 17 year olds to work with groups of younger students in the local and regional area. Students use their newly discovered knowledge and skills to inspire younger students with their enthusiasm and passion for geology. The student ambassadors work with cohorts of junior students to share learning through projects and lessons in previous GIFT subjects including the Rosetta space mission and Mediterranean geoscience. This scheme has provided younger students with valuable knowledge and skills and an awareness of post 16 courses but also offers ambassadors the chance to practice and learn transferrable skills beneficial to their future higher-education careers. The scheme has also allowed their passion for their subject to be shared with others. All of the 2016 Geoscience Ambassadors successfully went on to apply for degrees in geology or geoscience related disciplines at university. The ambassador scheme offers an alternative approach to supporting the engagement and understanding of the geosciences. By encouraging students to become Geoscience Ambassadors, they have the opportunity to compound their knowledge of the subjects as well as inspiring junior students who previously had little awareness of geoscience.

EarthCube's Assessment Framework: Ensuring Return on Investment

NASA Astrophysics Data System (ADS)

Lehnert, K.

2016-12-01

EarthCube is a community-governed, NSF-funded initiative to transform geoscience research by developing cyberinfrastructure that improves access, sharing, visualization, and analysis of all forms of geosciences data and related resources. EarthCube's goal is to enable geoscientists to tackle the challenges of understanding and predicting a complex and evolving solid Earth, hydrosphere, atmosphere, and space environment systems. EarthCube's infrastructure needs capabilities around data, software, and systems. It is essential for EarthCube to determine the value of new capabilities for the community and the progress of the overall effort to demonstrate its value to the science community and Return on Investment for the NSF. EarthCube is therefore developing an assessment framework for research proposals, projects funded by EarthCube, and the overall EarthCube program. As a first step, a software assessment framework has been developed that addresses the EarthCube Strategic Vision by promoting best practices in software development, complete and useful documentation, interoperability, standards adherence, open science, and education and training opportunities for research developers.

The Earth Science Women's Network: The Principles That Guide Our Mentoring

NASA Astrophysics Data System (ADS)

Adams, M. S.; Steiner, A. L.; Wiedinmyer, C.

2015-12-01

The Earth Science Women's Network (ESWN) began informally in 2002 as a way for six early career female atmospheric chemists to stay in contact and support each other. Twelve years later (2014), the ESWN formally became a non-profit organization with over 2000 members. The ESWN includes scientists from all disciplines of the geosciences with members located in over 50 countries. The ESWN is dedicated to career development, peer mentoring and community building for women in the geosciences. The mentoring philosophy of ESWN has evolved to include five main principles: 1.) Support community-driven mentoring, 2.) Encourage diverse mentoring approaches for diverse individuals, 3.) Facilitate mentoring across career phases, 4.) Promote combined personal and professional mentoring, 5.) Champion effective mentoring in a safe space. Surveys of ESWN members report gains in areas that are often considered barriers to career advancement, including recognition that they are not alone, new understanding of obstacles faced by women in science, and access to professional resources.

Bringing Grand Canyon to the College Campus: Assessment of Student Learning in the Geosciences Through Virtual Field Trip Games for Mobile Smart-Devices

NASA Astrophysics Data System (ADS)

Bursztyn, N.; Walker, A.; Shelton, B.; Pederson, J. L.

2015-12-01

Geoscience educators have long considered field trips to be the most effective way of attracting students into the discipline. A solution for bringing student-driven, engaging, kinesthetic field experiences to a broader audience lies in ongoing advances in mobile-communication technology. This NSF-TUES funded project developed three virtual field trip experiences for smartphones and tablets (on geologic time, geologic structures, and hydrologic processes), and then tested their performance in terms of student interest in geoscience as well as gains in learning. The virtual field trips utilize the GPS capabilities of smartphones and tablets, requiring the students to navigate outdoors in the real world while following a map on their smart device. This research, involving 873 students at five different college campuses, used analysis of covariance (ANCOVA) and multiple regression for statistical methods. Gains in learning across all participants are minor, and not statistically different between intervention and control groups. Predictors of gains in content comprehension for all three modules are the students' initial interest in the subject and their base level knowledge. For the Geologic Time and Structures modules, being a STEM major is an important predictor of student success. Most pertinent for this research, for Geologic Time and Hydrologic Processes, gains in student learning can be predicted by having completed those particular virtual field trips. Gender and race had no statistical impact, indicating that the virtual field trip modules have broad reach across student demographics. In related research, these modules have been shown to increase student interest in the geosciences more definitively than the learning gains here. Thus, future work should focus on improving the educational impact of mobile-device field trips, as their eventual incorporation into curricula is inevitable.

EarthCube - Results of Test Governance in Geoscience Cyberinfrastructure

NASA Astrophysics Data System (ADS)

Davis, R.; Allison, M. L.; Keane, C. M.; Robinson, E.

2016-12-01

In September 2016, the EarthCube Test Enterprise Governance Project completed its three-year long process to engage the community and test a demonstration governing organization with the goal of facilitating a community-led process on designing and developing a geoscience cyberinfrastructure to transform geoscience research. The EarthCube initiative is making an important transition from creating a coherent community towards adoption and implemention of technologies that can serve scientists working in and across many domains. The emerging concept of a "system of systems" approach to cyberinfrastructure architecture is a critical concept in the EarthCube program, but has not been fully defined. Recommendations from an NSF-appointed Advisory Committee include: a. developing a succinct definition of EarthCube; b. changing the community-elected governance approach towards structured rather than consensus-driven decision-making; c. restructuring the process to articulate program solicitations; and d. producing an effective implementation roadmap. These are seen as prerequisites to adoption of best practices, system concepts, and evolving to a production track. The EarthCube governing body is preparing responses to the Advisory Committee findings and recommendations with a target delivery date of late 2016 but broader involvement may be warranted. We conclude that there is ample justification to continue evolving to a governance framework that facilitates convergence on a system architecture that guides EarthCube activities and plays an influential role in making operational the EarthCube vision of cyberinfrastructure for the geosciences. There is widespread community expectation for support of a multiyear EarthCube governing effort to put into practice the science, technical, and organizational plans that are continuing to emerge. However, the active participants in EarthCube represent a small sub-set of the larger population of geoscientists.

MS PHD'S: Effective Pathways to Mentoring for Increasing Diversity in the Geoscience Workforce - What have we done? What can we still do?

NASA Astrophysics Data System (ADS)

Ricciardi, L.; Johnson, A.; Williamson Whitney, V.; Ithier-Guzman, W.; Johnson, A.; Braxton, L.

2011-12-01

In 2003 a young, African-American geoscientist and professor discovered significant gaps in the recruitment and retention of minority students within the post-secondary educational community and a subsequent correlation of underrepresentation within the geosciences workforce. From this research, a unique concept was born: The Minorities Striving and Pursuing Higher Degrees of Success in Earth System Science Professional Development Program (MS PHD'S PDP). This program was founded upon a vision that minorities can and should play a role in facilitating a network to attract, retain and increase minority representation in the geosciences workforce. In 2003, the pilot MS PHD'S program focused on a simple grass roots concept of effective mentoring and professional development administered by and for minorities through professional development activities. Today the program has grown to an impressive number of alumni who, in addition to establishing careers in the ESS professional workforce, also return to mentor the next generation of upcoming minority geoscientists. Alumni, mentors and current participants not only experience what has grown into a three-phase program but also enjoy enhanced benefits of ongoing interaction through social media, list-servs and webinars. While keeping its feet firmly planted in its grass-roots philosophy of effective mentoring and professional development by and for minorities, the MS PHD'S program looks to the future, by asking the question, "What can we do next to ensure the future of maintaining and growing diverse representation in the geosciences workforce?" Looking ahead, future goals for the program include increasing its pilot representation motto of "by and for minorities", exploring new technologies and digital tools, and expanding its supportive network of distinguished academicians, scientific organizations, industry partners, alumni, peers, and representatives of non-science disciplines.

The Role of Geoscience Education Research in the Consilience between Science of the Mind and Science of the Natural World

ERIC Educational Resources Information Center

Shipley, Thomas F.; Tikoff, Basil

2017-01-01

This manuscript addresses the potential role of geoscience education research in understanding geoscience expert practice. We note the similarity between the perception-action framework of Ulric Neisser (Neisser, 1976) and the observation-prediction framework used by geoscience practitioners. The consilience between these two approaches is that…

Engaging Undergraduates in the New York City S-SAFE Internship Program: An Impetus to Raise Geoscience Awareness

ERIC Educational Resources Information Center

Blake, Reginald A.; Liou-Mark, Janet; Blackburn, Noel; Chan, Christopher; Yuen-Lau, Laura

2015-01-01

To engender and raise awareness to the geosciences, a geoscience research project and a corresponding geoscience internship program were designed around plume dispersion dynamics within and above the New York City subway system. Federal, regional, and local agencies partnered with undergraduate students from minority-serving institutions to…

Lesson's-learned from a 2003-2006 USA-Honduras NGO and University Geosciences Education Partnership in Land use Land / Land Cover Change Analysis using Remote Sensing and GPS

NASA Astrophysics Data System (ADS)

Ford, R. E.

2006-12-01

Between 2004 and 2006 the Loma Linda University ESSE21 Mesoamerican Project (Earth System Science Education for the 21st Century) collaborated with a series of academic, NGO (nongovernmental) and government agencies, including a USAID (United States Agency for International Development) integrated environmental resource management project to: a) build the human and technical capacity of local partners in the use of geospatial technologies, e.g. GIS, GPS, Remote Sensing, b) improve their capacity to apply these tools to biodiversity, health, sustainability, protected-area management, and other NRM (Natural Resource Management) decision-making needs and problems, and c) establish long term institutional relationships for teacher/student exchange, including development of joint curricula and research projects focused on health geoinformatics as well as sustainable development. Much of this has contributed toward a new "geotourism" effort adopted by Honduras called the SAVE Honduras strategy (Scientific, Academic, Volunteer, Educational). A central element of this initiative is to increase joint collaborative research and learning together by students and faculty at US universities working with Honduran institutions (private and public). See SAVE Strategy page = http://www.fundacionsave.com/home_eng.html In the presentation we describe our experience over the last three years collaborating with key partners such as the Central American Observatory of Suyapa based at the UNAH (Universidad Nacional Autónoma de Honduras) which has opened a new GIS/Remote Sensing Laboratory. We also collaborated closely with CURLA (Centro Universitario Regional del Litoral Atlántico) located near La Ceiba--a land grant-type institution- -to support outreach and extension activities by students and staff to local-level NGOs and community groups dealing with conservation, hazards mitigation, biodiversity, fisheries and related problems. We have also participated in joint "informal education" efforts doing environmental and ecotourism outreach with groups such as the Hugh Parkey Foundation and EarthWatch Institute in Belize and others in Honduras such as FUCSA (Fundacion Cuero y Salado), FUPNAPIB (Fundacion Parque Nacional Pico Bonito), REHDES (Red Ecologista Hondurena para el Desarrollo Sostenible), and SMBC (Sociedad Mesoamericana para la Biologia y Conservacion). See more about the projects on water resources, herpetofauna on the Pacific coast, and the West Indian manatee at: http://resweb.llu.edu/rford/ Lessons learned about designing, organizing, implementing, and financing such geosciences educational partnerships will be presented as well as describing "next steps". Suggestions about how other universities could join with us will be also proposed.

Enabling Discoveries in Earth Sciences Through the Geosciences Network (GEON)

NASA Astrophysics Data System (ADS)

Seber, D.; Baru, C.; Memon, A.; Lin, K.; Youn, C.

2005-12-01

Taking advantage of the state-of-the-art information technology resources GEON researchers are building a cyberinfrastructure designed to enable data sharing, semantic data integration, high-end computations and 4D visualization in easy-to-use web-based environments. The GEON Network currently allows users to search and register Earth science resources such as data sets (GIS layers, GMT files, geoTIFF images, ASCII files, relational databases etc), software applications or ontologies. Portal based access mechanisms enable developers to built dynamic user interfaces to conduct advanced processing and modeling efforts across distributed computers and supercomputers. Researchers and educators can access the networked resources through the GEON portal and its portlets that were developed to conduct better and more comprehensive science and educational studies. For example, the SYNSEIS portlet in GEON enables users to access in near-real time seismic waveforms from the IRIS Data Management Center, easily build a 3D geologic model within the area of the seismic station(s) and the epicenter and perform a 3D synthetic seismogram analysis to understand the lithospheric structure and earthquake source parameters for any given earthquake in the US. Similarly, GEON's workbench area enables users to create their own work environment and copy, visualize and analyze any data sets within the network, and create subsets of the data sets for their own purposes. Since all these resources are built as part of a Service-oriented Architecture (SOA), they are also used in other development platforms. One such platform is Kepler Workflow system which can access web service based resources and provides users with graphical programming interfaces to build a model to conduct computations and/or visualization efforts using the networked resources. Developments in the area of semantic integration of the networked datasets continue to advance and prototype studies can be accessed via the GEON portal at www.geongrid.org

Global Unique Identification of Geoscience Samples: The International Geo Sample Number (IGSN) and the System for Earth Sample Registration (SESAR)

NASA Astrophysics Data System (ADS)

Lehnert, K. A.; Goldstein, S. L.; Vinayagamoorthy, S.; Lenhardt, W. C.

2005-12-01

Data on samples represent a primary foundation of Geoscience research across disciplines, ranging from the study of climate change, to biogeochemical cycles, to mantle and continental dynamics and are key to our knowledge of the Earth's dynamical systems and evolution. Different data types are generated for individual samples by different research groups, published in different papers, and stored in different databases on a global scale. The utility of these data is critically dependent on their integration. Such integration can be achieved within a Geoscience Cyberinfrastructure, but requires unambiguous identification of samples. Currently, naming of samples is arbitrary and inconsistent and therefore severely limits our ability to share, link, and integrate sample-based data. Major problems include name duplication, and changing of names as a sample is passed along over many years to different investigators. SESAR, the System for Earth Sample Registration (http://www.geosamples.org), addresses this problem by building a registry that generates and administers globally unique identifiers for Geoscience samples: the International Geo Sample Number (IGSN). Implementation of the IGSN in data publication and digital data management will dramatically advance interoperability among information systems for sample-based data, opening an extensive range of new opportunities for discovery and for interdisciplinary approaches in research. The IGSN will also facilitate the ability of investigators to build on previously collected data on samples as new measurements are made or new techniques are developed. With potentially broad application to all types of Geoscience samples, SESAR is global in scope. It is a web-based system that can be easily accessed by individual users through an interactive web interface and by distributed client systems via standard web services. Samples can be registered individually or in batches and at various levels of granularity from entire cores or dredges or sample suites to individual samples to sub-samples such as splits and separates. Relationships between `parent' and `child' samples are tracked. The system generates bar codes that users can download as images for labeling purposes. SESAR released a beta version of the registry in April 2005 that allows users to register a limited range of sample types. Identifiers generated by the beta version will remain valid when SESAR moves into its operational stage. Since then more than 3700 samples have been registered in SESAR. Registration of samples at a central clearinghouse will automatically build a global catalog of Geoscience samples, which will become a hugely valuable resource for the Geoscience community that allows more efficient planning of field and laboratory projects and facilitates sharing of samples, which will help build more comprehensive data sets for individual samples. The SESAR catalog will provide links to sample profiles on external systems that hold data about samples, thereby enabling users to easily obtain complete information about samples.

Results of student-peer collaboration in the development of the Geoscience Student Data Network

NASA Astrophysics Data System (ADS)

Block, K. A.; Snyder, W. S.; Williams, N.; Rudolph, E.

2012-12-01

The Geoscience Student Data Network (GSDNet) is an NSF-CCLI project to develop a software application that facilitates student collaboration and data analysis. Cyberinfrastructure development is accompanied by a three-course curriculum that includes a field component implemented jointly at City College of New York (CCNY) and Boise State University (BSU). We report on the challenges of utilizing existing social networking technology for student collaboration and the hurdles of real-time information exchange on heavily taxed networks and facilities. The field component and research project currently underway is engaging eight students from CCNY and their BSU peer-mentors. Students are characterizing a geothermal prospect in Idaho by combining data collected in the field, laboratory studies and cyberinfrastructure outlets using the GSDNet prototype. We will summarize results of student projects from data collection, metadata documentation, online collaboration, and project dissemination.

AGU scientists meet with legislators during Geosciences Congressional Visits Day

NASA Astrophysics Data System (ADS)

Uhlenbrock, Kristan

2011-10-01

This year marks the fourth annual Geosciences Congressional Visits Day (Geo-CVD), in which scientists from across the nation join together in Washington, D. C., to meet with their legislators to discuss the importance of funding for Earth and space sciences. AGU partnered with seven other Earth and space science organizations to bring more than 50 scientists, representing 23 states, for 2 days of training and congressional visits on 20-21 September 2011. As budget negotiations envelop Congress, which must find ways to agree on fiscal year (FY) 2012 budgets and reduce the deficit by $1.5 trillion over the next 10 years, Geo-CVD scientists seized the occasion to emphasize the importance of federally funded scientific research as well as science, technology, engineering, and math (STEM) education. Cuts to basic research and STEM education could adversely affect innovation, stifle future economic growth and competitiveness, and jeopardize national security.

Improving Geoscience Outreach Through Multimedia Enhanced Web Sites - An Example From Connecticut

NASA Astrophysics Data System (ADS)

Hyatt, J. A.; Coron, C. R.; Schroeder, T. J.; Fleming, T.; Drzewiecki, P. A.

2005-12-01

Although large governmental web sites (e.g. USGS, NASA etc.) are important resources, particularly in relation to phenomena with global to regional significance (e.g. recent Tsunami and Hurricane disasters), smaller academic web portals continue to make substantive contributions to web-based learning in the geosciences. The strength of "home-grown" web sites is that they easily can be tailored to specific classes, they often focus on local geologic content, and they potentially integrate classroom, laboratory, and field-based learning in ways that improve introductory classes. Furthermore, innovative multimedia techniques including virtual reality, image manipulations, and interactive streaming video can improve visualization and be particularly helpful for first-time geology students. This poster reports on one such web site, Learning Tools in Earth Science (LTES, http://www.easternct .edu/personal/faculty/hyattj/LTES-v2/), a site developed by geoscience faculty at two state institutions. In contrast to some large web sites with media development teams, LTES geoscientists, with strong support from media and IT service departments, are responsible for geologic content and verification, media development and editing, and web development and authoring. As such, we have considerable control over both content and design of this site. At present the main content modules for LTES include "mineral" and "virtual field trip" links. The mineral module includes an interactive mineral gallery, and a virtual mineral box of 24 unidentified samples that are identical to those used in some of our classes. Students navigate an intuitive web portal to manipulate images and view streaming video segments that explain and undertake standard mineral identification tests. New elements highlighted in our poster include links to a virtual petrographic microscope, in which users can manipulate images to simulate stage rotation in both plane- and cross-polarized light. Virtual field trips include video-based excursions to sites in Georgia, Connecticut and Greenland. New to these VFT's is the integration of "virtual walks" in which users are able to navigate through some field sites in a virtual sense. Development of this resource is ongoing, but response from students, faculty outside of Earth Science and K-12 instructors indicate that this small web site can provide useful resources for those educators utilizing web-based learning in their courses. .edu/personal/faculty/hyattj/LTES-v2/

Central Colorado Assessment Project - Application of integrated geologic, geochemical, biologic, and mineral resource studies

USGS Publications Warehouse

Klein, T.L.; Church, S.E.; Caine, Jonathan S.; Schmidt, T.S.; deWitt, E.H.

2008-01-01

Cooperative studies by USDA Forest Service, National Park Service supported by the USGS Mineral Resources Program (MRP), and National Cooperative Geologic Mapping Programs (NCGMP) contributed to the mineral-resource assessment and included regional geologic mapping at the scale 1:100,000, collection and geochemical studies of stream sediments, surface water, and bedrock samples, macroinvertebrate and biofilm studies in the riparian environment, remote-sensing studies, and geochronology. Geoscience information available as GIS layers has improved understanding of the distribution of metallic, industrial, and aggregate resources, location of areas that have potential for their discovery or development, helped to understand the relation of tectonics, magmatism, and paleohydrology to the genesis of the metal deposits in the region, and provided insight on the geochemical and environmental effects that historical mining and natural, mineralized rock exposures have on surface water, ground water, and aquatic life.

Use of several Cloud Computing approaches for climate modelling: performance, costs and opportunities

NASA Astrophysics Data System (ADS)

Perez Montes, Diego A.; Añel Cabanelas, Juan A.; Wallom, David C. H.; Arribas, Alberto; Uhe, Peter; Caderno, Pablo V.; Pena, Tomas F.

2017-04-01

Cloud Computing is a technological option that offers great possibilities for modelling in geosciences. We have studied how two different climate models, HadAM3P-HadRM3P and CESM-WACCM, can be adapted in two different ways to run on Cloud Computing Environments from three different vendors: Amazon, Google and Microsoft. Also, we have evaluated qualitatively how the use of Cloud Computing can affect the allocation of resources by funding bodies and issues related to computing security, including scientific reproducibility. Our first experiments were developed using the well known ClimatePrediction.net (CPDN), that uses BOINC, over the infrastructure from two cloud providers, namely Microsoft Azure and Amazon Web Services (hereafter AWS). For this comparison we ran a set of thirteen month climate simulations for CPDN in Azure and AWS using a range of different virtual machines (VMs) for HadRM3P (50 km resolution over South America CORDEX region) nested in the global atmosphere-only model HadAM3P. These simulations were run on a single processor and took between 3 and 5 days to compute depending on the VM type. The last part of our simulation experiments was running WACCM over different VMS on the Google Compute Engine (GCE) and make a comparison with the supercomputer (SC) Finisterrae1 from the Centro de Supercomputacion de Galicia. It was shown that GCE gives better performance than the SC for smaller number of cores/MPI tasks but the model throughput shows clearly how the SC performance is better after approximately 100 cores (related with network speed and latency differences). From a cost point of view, Cloud Computing moves researchers from a traditional approach where experiments were limited by the available hardware resources to monetary resources (how many resources can be afforded). As there is an increasing movement and recommendation for budgeting HPC projects on this technology (budgets can be calculated in a more realistic way) we could see a shift on the trends over the next years to consolidate Cloud as the preferred solution.

Basic Energy Sciences Program Update

DOE Office of Scientific and Technical Information (OSTI.GOV)

None, None

2016-01-04

The U.S. Department of Energy’s (DOE) Office of Basic Energy Sciences (BES) supports fundamental research to understand, predict, and ultimately control matter and energy at the electronic, atomic, and molecular levels to provide the foundations for new energy technologies and to support DOE missions in energy, environment, and national security. The research disciplines covered by BES—condensed matter and materials physics, chemistry, geosciences, and aspects of physical biosciences— are those that discover new materials and design new chemical processes. These disciplines touch virtually every aspect of energy resources, production, conversion, transmission, storage, efficiency, and waste mitigation. BES also plans, constructs, andmore » operates world-class scientific user facilities that provide outstanding capabilities for imaging and spectroscopy, characterizing materials of all kinds ranging from hard metals to fragile biological samples, and studying the chemical transformation of matter. These facilities are used to correlate the microscopic structure of materials with their macroscopic properties and to study chemical processes. Such experiments provide critical insights to electronic, atomic, and molecular configurations, often at ultrasmall length and ultrafast time scales.« less

Enabling Remote Activity: Using mobile technology for remote participation in geoscience fieldwork

NASA Astrophysics Data System (ADS)

Davies, Sarah; Collins, Trevor; Gaved, Mark; Bartlett, Jessica; Valentine, Chris; McCann, Lewis

2010-05-01

Field-based activities are regarded as essential to the development of a range of professional and personal skills within the geosciences. Students enjoy field activities, preferring these to learning with simulations (Spicer and Stratford 2001), and these improve deeper learning and understanding (Kern and Carpenter, 1984; Elkins and Elkins, 2007). However, some students find it difficult to access these field-based learning opportunities. Field sites may be remote and often require travel across uneven, challenging or potentially dangerous terrain. Mobility-impaired students are particularly limited in their opportunities to participate in field-based learning activities and, as higher education institutions have a responsibility to provide inclusive opportunities for students (UK Disability Discrimination Act 1995, UK Special Education Needs and Disability Rights Act 2001), the need for inclusive fieldwork learning is being increasingly recognised. The Enabling Remote Activity (ERA) project has been investigating how mobile communications technologies might allow field learning experiences to be brought to students who would otherwise find it difficult to participate, and also to enhance activities for all participants. It uses a rapidly deployable, battery-powered wireless network to transmit video, audio, and high resolution still images to connect participants at an accessible location with participants in the field. Crucially, the system uses a transient wireless network, allowing multiple locations to be explored during a field visit, and for plans to be changed dynamically if required. Central to the concept is the requirement for independent investigative learning: students are enabled to participate actively in the learning experience and to direct the investigations, as opposed to being simply remote viewers of the experience. Two ways of using the ERA system have been investigated: remote access and collaborative groupwork. In 2006 and 2008 remote access was used to enable mobility-impaired students to take part in and complete a field course. This involved connecting the student in an accessible vehicle located close to the field site, via a wireless network, to a geologist in the field. The geologist worked alongside the general body of students and the field tutor as each geological site was investigated. Two-way communications allowed the student to guide the geologist to provide video panoramas of the area, to select areas of interest for further study and to obtain high resolution images of specific points. The students were able to work through the field activities alongside the rest of the student group. A collaborative groupwork trial (2007) was used to connect two groups of students; one in an accessible laboratory, the other at a field site. Traditionally, students collect data in the field and analyze it on return to the laboratory; this system proposes a more rapid collection and analysis procedure, with information being transmitted between sites with field and laboratory participants having their own distinct, significant roles within the learning activity. This project recently received an award at the 2008 Handheld Learning Conference and a HEFCE sponsored Open University Teaching Award. In contrast to the use of ‘virtual fieldwork' that aims to provide simulations or a resource for a student to use, the focus of this project is on how technology can be used to support actual fieldwork activities. This approach has been trialled now over three field seasons, with students using the system to remotely participate in fieldwork activities. Interviews with tutors and students have shown that this was perceived as valuable and allowed participants to achieve the learning objectives of the course alongside their peers. The challenges of remote fieldwork concern the co-ordination of students' activities, the integration of remote and field activities and practical issues of lightweight, easy-to-use, robust technologies and the provision of a reliable communications network. References Elkins, J.T. & Elkins, N.M.L. (2007) Teaching geology in the field: significant geoscience concept gains in entirely field-based introductory geology courses. Journal of Geoscience Education, 55 (2), 126-132. Kern, E. and Carpenter, J. (2004). Enhancement of student values, interests and attitudes in Earth Science through a field-oriented approach. Journal of Geological Education, 32 (5), 299-305. Spicer, J. I. and Stratford, J. (2001) Student perceptions of a virtual field trip to replace a real field trip. Journal of Computer Assisted Learning, 17(4), 345-354.

Geocognition Research: An International Discipline (Invited)

NASA Astrophysics Data System (ADS)

Libarkin, J.

2009-12-01

Geocognition and geoscience education research have experienced a dramatic increase in research productivity and graduate student training in the past decade. At this writing, over twelve U.S. graduate programs dedicated to geocognition and geoscience education research exist within geoscience departments, with numerous other programs housed within education. International research programs are experiencing similar increases in these research domains. This insurgence of graduate training opportunities is due in large part to several factors, including: An increased awareness of the importance of Earth Systems Science to public understanding of science, particularly in light of global concern about climate change; new funding opportunities for science education, cognitive science, and geoscience education research; and, engagement of a significant part of the geosciences and education communities in writing new standards for Earth Systems literacy. Existing research programs blend geoscience content knowledge with research expertise in education, cognitive science, psychology, sociology and related disciplines. Research projects reflect the diversity of interests in geoscience teaching and learning, from investigations of pedagogical impact and professional development to studies of fundamental geocognitive processes.

Worldwide Emerging Environmental Issues Affecting the U.S. Military. February 2010

DTIC Science & Technology

2010-02-01

claims study http://www.independent.co.uk/environment/nature/ oceans -acidity-rate-is-soaring-claims-study-1899536.html World’s coral reefs could...GDP is linked to coastal natural resources. Already, 40% of coral reefs and 50% of mangrove swamps have been lost. Coral reefs generate an estimated...Geoscience, the current rate of ocean acidification is up to 10 times faster than 55 million years ago—the last time deep oceans were so acidic. The

Incorporating Geoscience, Field Data Collection Workflows into Software Developed for Mobile Devices

NASA Astrophysics Data System (ADS)

Vieira, D. A.; Mookerjee, M.; Matsa, S.

2014-12-01

Modern geological sciences depend heavily on investigating the natural world in situ, i.e., within "the field," as well as managing data collections in the light of evolving advances in technology and cyberinfrastructure. To accelerate the rate of scientific discovery, we need to expedite data collection and management in such a way so as to not interfere with the typical geoscience, field workflow. To this end, we suggest replacing traditional analog methods of data collection, such as the standard field notebook and compass, with primary digital data collection applications. While some field data collecting apps exist for both the iOS and android operating systems, they do not communicate with each other in an organized data collection effort. We propose the development of a mobile app that coordinates the collection of GPS, photographic, and orientation data, along with field observations. Additionally, this application should be able to pair with other devices in order to incorporate other sensor data. In this way, the app can generate a single file that includes all field data elements and can be synced to the appropriate database with ease and efficiency. We present here a prototype application that attempts to illustrate how digital collection can be integrated into a "typical" geoscience, field workflow. The purpose of our app is to get field scientists to think about specific requirements for the development of a unified field data collection application. One fundamental step in the development of such an app is the community-based, decision-making process of adopting certain data/metadata standards and conventions. In August of 2014, on a four-day field trip to Yosemite National Park and Owens Valley, we engaged a group of field-based geologists and computer/cognitive scientists to start building a community consensus on these cyberinfrastructure-related issues. Discussing the unique problems of field data recording, conventions, storage, representation, standardization, documentation, and management, while in the field, creates a unique opportunity to address critical issues with regards to advancing the development of cyberinfrastructure for the field-based geosciences while facilitating the combining of our datasets with those of other geoscience subdisciplines.

Growing Community Roots for the Geosciences in Miami, Florida, A Program Aimed at High School and Middle School Students to Increase Awareness of Career and Educational Opportunities in the Geosciences

NASA Astrophysics Data System (ADS)

Whitman, D.; Hickey-Vargas, R.; Gebelein, J.; Draper, G.; Rego, R.

2013-12-01

Growing Community Roots for the Geosciences is a 2-year pilot recruitment project run by the Department of Earth and Environment at Florida International University (FIU) and funded by the NSF OEDG (Opportunities for Enhancing Diversity in the Geosciences) program. FIU, the State University of Florida in Miami is a federally recognized Minority Serving Institution with over 70% of the undergraduate population coming from groups underrepresented in the geoscience workforce. The goal of this project is to inform students enrolled in the local middle and high schools to career opportunities in the geosciences and to promote pathways for underrepresented groups to university geoscience degree programs. The first year's program included a 1-week workshop for middle school teachers and a 2-week summer camp aimed at high school students in the public school system. The teacher workshop was attended by 20 teachers who taught comprehensive and physical science in grades 6-8. It included lectures on geoscience careers, fundamental concepts of solid earth and atmospheric science, hands on exercises with earth materials, fossils and microscopy, interpretation of landform with Google Earth imagery, and a field trip to a local working limestone quarry. On the first day of the workshop, participants were surveyed on their general educational background in science and their familiarity and comfort with teaching basic geoscience concepts. On the final day, the teachers participated in a group discussion where we discussed how to make geoscience topics and careers more visible in the school curriculum. The 2-week summer camp was attended by 21 students entering grades 9-12. The program included hands on exercises on geoscience and GIS concepts, field trips to local barrier islands, the Everglades, a limestone quarry and a waste to energy facility, and tours of the NOAA National Hurricane Center and the FIU SEM lab. Participants were surveyed on their general educational background in math and science as well as their general interest in geoscience careers. In separate focus groups, participants were queried on better ways of interesting high school students in geoscience majors. Suggestions included visits by faculty and college students to high schools and using social media promote events and activities

My Experience as a Student Participant in the Institute for Geophysics/Huston-Tillotson University Geodiversity Project

NASA Astrophysics Data System (ADS)

Putman, N.; Ellins, K.; Holt, J.; Olson, H. C.

2006-12-01

As a senior pre-service teacher at Huston-Tillotson University, a minority-serving institution in Texas, I found myself in need of a science course and reluctantly enrolled in "Special Topics in the Geosciences," a survey course taught by visiting scientists from The University of Texas at Austin's Institute for Geophysics (UTIG). I had no idea what the geosciences were about. On the first day of class we took a test and I began to feel a sense of foreboding, but after speaking with the instructors, I left filled with excitement. With my limited background in science, I knew that the class was going to be challenging and require a lot of studying. I took every opportunity offered in the class to learn more about the geosciences. If there was a field trip, I went. If there was an opportunity for me to speak to children about what I learned, I did. For example, I participated in the Explore UT open house event where, rather than being an observer as I had expected, I found myself explaining earthquake seismology to students, parents and visitors. The experience was pivotal. As I explained to a small group of 3rd graders how they could use computer applications to observe and understand seismic waves, I realized I wanted to be a science teacher and not an elementary level-teacher as I had planned. Since completing "Special Topics in the Geosciences," I've been an undergraduate research assistant at UTIG. Over the summer, I adapted approximately ten existing UTIG Earth Science learning activities into the 5-E instructional model for the fall 2006 professional development Earth Science Revolution Workshops for in- service teachers, and I developed a new lesson on tides for these workshops. I also participated in presenting both a workshop for minority-serving elementary teachers and a class for alternative certification teachers at HTU. In early September, I joined a group of scientists, engineers, and space-suited "astronauts" in the Arizona desert near Meteor Crater to "practice" for future human missions to Mars as a participant in NASA's Desert Research and Technology Studies (RATS) project. My role was to help scientists and engineers with experiments to determine the efficacy of Ground Penetrating Radar in locating buried ice (water) and other resources, such as metals, and to translate my experience into K-12 classroom activities. In the spring/summer of 2007 I expect to participate in a marine geophysical cruise offshore Panama and Costa Rica. The immersion in science, the opportunities to be part of scientific research teams, my daily interaction with scientists and graduate students, the mentoring from research scientists at UTIG, and the respect shown to me for transforming their science into interesting projects for K-12 students and teachers have been critical elements in my decision to pursue science teaching as a career.

Building on the Success of Increasing Diversity in the Geosciences: A Bridging Program From Middle School to College

NASA Astrophysics Data System (ADS)

Kovacs, T.; Robinson, D.; Suleiman, A.; Maggi, B.

2004-12-01

A bridging program to increase the diversity in the geosciences was created at Hampton University (HU) to inspire underrepresented minorities to pursue an educational path that advances them towards careers in the geosciences. Three objectives were met to achieve this goal. First, we inspired a diverse population of middle and high school students outside of the classroom by providing an after school geoscience club, a middle school geoscience summer enrichment camp, and a research/mentorship program for high school students. Second, we helped fill the need for geoscience curriculum content requested of science teachers who work primarily with underrepresented middle school populations by providing a professional development workshop at HU led by geoscience professors, teachers, and science educators. Third, we built on the successful atmospheric sciences research and active Ph.D. program by developing our geoscience curriculum including the formation of a new space, earth, and atmospheric sciences minor. All workshops, camps, and clubs have been full or nearly full each year despite restrictions on participants repeating any of the programs. The new minor has 11 registered undergraduates and the total number of students in these classes has been increasing. Participants of all programs gave the quality of the program good ratings and participant perceptions and knowledge improved throughout the programs based on pre-, formative, and summative assessments. The ultimate goal is to increase the number of degrees granted to underrepresented minorities in the geosciences. We have built a solid foundation with our minor that prepares students for graduate degrees in the geosciences and offer a graduate degree in physics with a concentration in the atmospheric sciences. However, it's from the geoscience pipeline that students will come into our academic programs. We expect to continue to develop these formal and informal education programs to increase our reputation and utilize the network of schools with which we have built relationships to recruit underrepresented minority students into our academic programs. We also plan to continue to enhance our undergraduate minor and graduate degree programs to build a self-sustaining graduate degree-granting program in the geosciences.

Resources for Designing, Selecting and Teaching with Visualizations in the Geoscience Classroom

NASA Astrophysics Data System (ADS)

Kirk, K. B.; Manduca, C. A.; Ormand, C. J.; McDaris, J. R.

2009-12-01

Geoscience is a highly visual field, and effective use of visualizations can enhance student learning, appeal to students’ emotions and help them acquire skills for interpreting visual information. The On the Cutting Edge website, “Teaching Geoscience with Visualizations” presents information of interest to faculty who are teaching with visualizations, as well as those who are designing visualizations. The website contains best practices for effective visualizations, drawn from the educational literature and from experts in the field. For example, a case is made for careful selection of visualizations so that faculty can align the correct visualization with their teaching goals and audience level. Appropriate visualizations will contain the desired geoscience content without adding extraneous information that may distract or confuse students. Features such as labels, arrows and contextual information can help guide students through imagery and help to explain the relevant concepts. Because students learn by constructing their own mental image of processes, it is helpful to select visualizations that reflect the same type of mental picture that students should create. A host of recommended readings and presentations from the On the Cutting Edge visualization workshops can provide further grounding for the educational uses of visualizations. Several different collections of visualizations, datasets with visualizations and visualization tools are available on the website. Examples include animations of tsunamis, El Nino conditions, braided stream formation and mountain uplift. These collections are grouped by topic and range from simple animations to interactive models. A series of example activities that incorporate visualizations into classroom and laboratory activities illustrate various tactics for using these materials in different types of settings. Activities cover topics such as ocean circulation, land use changes, earthquake simulations and the use of Google Earth to explore geologic processes. These materials can be found at http://serc.carleton.edu/NAGTWorkshops/visualization. Faculty and developers of visualization tools are encouraged to submit teaching activities, references or visualizations to the collections.

Connecting real-time data to algorithms and databases: EarthCube's Cloud-Hosted Real-time Data Services for the Geosciences (CHORDS)

NASA Astrophysics Data System (ADS)

Daniels, M. D.; Graves, S. J.; Kerkez, B.; Chandrasekar, V.; Vernon, F.; Martin, C. L.; Maskey, M.; Keiser, K.; Dye, M. J.

2015-12-01

The Cloud-Hosted Real-time Data Services for the Geosciences (CHORDS) project was funded under the National Science Foundation's EarthCube initiative. CHORDS addresses the ever-increasing importance of real-time scientific data in the geosciences, particularly in mission critical scenarios, where informed decisions must be made rapidly. Access to constant streams of real-time data also allow many new transient phenomena in space-time to be observed, however, much of these streaming data are either completely inaccessible or only available to proprietary in-house tools or displays. Small research teams do not have the resources to develop tools for the broad dissemination of their unique real-time data and require an easy to use, scalable, cloud-based solution to facilitate this access. CHORDS will make these diverse streams of real-time data available to the broader geosciences community. This talk will highlight a recently developed CHORDS portal tools and processing systems which address some of the gaps in handling real-time data, particularly in the provisioning of data from the "long-tail" scientific community through a simple interface that is deployed in the cloud, is scalable and is able to be customized by research teams. A running portal, with operational data feeds from across the nation, will be presented. The processing within the CHORDS system will expose these real-time streams via standard services from the Open Geospatial Consortium (OGC) in a way that is simple and transparent to the data provider, while maximizing the usage of these investments. The ingestion of high velocity, high volume and diverse data has allowed the project to explore a NoSQL database implementation. Broad use of the CHORDS framework by geoscientists will help to facilitate adaptive experimentation, model assimilation and real-time hypothesis testing.

Cloud-Hosted Real-time Data Services for the Geosciences (CHORDS)

NASA Astrophysics Data System (ADS)

Daniels, M. D.; Graves, S. J.; Kerkez, B.; Chandrasekar, V.; Vernon, F.; Martin, C. L.; Maskey, M.; Keiser, K.; Dye, M. J.

2015-12-01

The Cloud-Hosted Real-time Data Services for the Geosciences (CHORDS) project, funded as part of NSF's EarthCube initiative, addresses the ever-increasing importance of real-time scientific data, particularly in mission critical scenarios, where informed decisions must be made rapidly. Advances in the distribution of real-time data are leading many new transient phenomena in space-time to be observed, however, real-time decision-making is infeasible in many cases as these streaming data are either completely inaccessible or only available to proprietary in-house tools or displays. This lack of accessibility prohibits advanced algorithm and workflow development that could be initiated or enhanced by these data streams. Small research teams do not have resources to develop tools for the broad dissemination of their valuable real-time data and could benefit from an easy to use, scalable, cloud-based solution to facilitate access. CHORDS proposes to make a very diverse suite of real-time data available to the broader geosciences community in order to allow innovative new science in these areas to thrive. This presentation will highlight recently developed CHORDS portal tools and processing systems aimed at addressing some of the gaps in handling real-time data, particularly in the provisioning of data from the "long-tail" scientific community through a simple interface deployed in the cloud. The CHORDS system will connect these real-time streams via standard services from the Open Geospatial Consortium (OGC) and does so in a way that is simple and transparent to the data provider. Broad use of the CHORDS framework will expand the role of real-time data within the geosciences, and enhance the potential of streaming data sources to enable adaptive experimentation and real-time hypothesis testing. Adherence to community data and metadata standards will promote the integration of CHORDS real-time data with existing standards-compliant analysis, visualization and modeling tools.

The ENGAGE Workshop: Encouraging Networks between Geoscientists and Geoscience Education Researchers

NASA Astrophysics Data System (ADS)

Hubenthal, M.; LaDue, N.; Taber, J.

2015-12-01

The geoscience education community has made great strides in the study of teaching and learning at the undergraduate level, particularly with respect to solid earth geology. Nevertheless, the 2012 National Research Council report, Discipline-based Education Research: Understanding and Improving Learning in Undergraduate Science and Engineering suggests that the geosciences lag behind other science disciplines in the integration of education research within the discipline and the establishment of a broad research base. In January 2015, early career researchers from earth, atmospheric, ocean, and polar sciences and geoscience education research (GER) gathered for the ENGAGE workshop. The primary goal of ENGAGE was to broaden awareness of discipline-based research in the geosciences and catalyze relationships and understanding between these groups of scientists. An organizing committee of geoscientists and GERs designed a two-day workshop with a variety of activities to engage participants in the establishment of a shared understanding of education research and the development of project ideas through collaborative teams. Thirty-three participants were selected from over 100 applicants, based on disciplinary diversity and demonstrated interest in geoscience education research. Invited speakers and panelists also provided examples of successful cross-disciplinary collaborations. As a result of this workshop, participants indicated that they gained new perspectives on geoscience education and research, networked outside of their discipline, and are likely to increase their involvement in geoscience education research. In fact, 26 of 28 participants indicated they are now better prepared to enter into cross-disciplinary collaborations within the next year. The workshop evaluation revealed that the physical scientists particularly valued opportunities for informal networking and collaborative work developing geoscience education research projects. Meanwhile, GERs valued opportunities to discuss the boundaries of outreach, evaluation, and research and the potential next steps to advance geoscience education. Recommendations from the workshop are well aligned with earlier reports, and along with those documents, contributes to a path forward for geoscience education.

Academic provenance: Investigation of pathways that lead students into the geosciences

NASA Astrophysics Data System (ADS)

Houlton, Heather R.

Pathways that lead students into the geosciences as a college major have not been fully explored in the current literature, despite the recent studies on the "geoscience pipeline model." Anecdotal evidence suggests low quality geoscience curriculum in K-12 education, lack of visibility of the discipline and lack of knowledge about geoscience careers contribute to low geoscience enrollments at universities. This study investigated the reasons why college students decided to major in the geosciences. Students' interests, experiences, motivations and desired future careers were examined to develop a pathway model. In addition, self-efficacy was used to inform pathway analyses, as it is an influential factor in academic major and career choice. These results and interpretations have strong implications for recruitment and retention in academia and industry. A semi-structured interview protocol was developed, which was informed by John Flanagan's critical incident theory. The responses to this interview were used to identify common experiences that diverse students shared for reasons they became geoscience majors. Researchers used self-efficacy theory by Alfred Bandura to assess students' pathways. Seventeen undergraduate geoscience majors from two U.S. Midwest research universities were sampled for cross-comparison and analysis. Qualitative analyses led to the development of six categorical steps for the geoscience pathway. The six pathway steps are: innate attributes/interest sources, pre-college critical incidents, college critical incidents, current/near future goals, expected career attributes and desired future careers. Although, how students traversed through each step was unique for individuals, similar patterns were identified between different populations in our participants: Natives, Immigrants and Refugees. In addition, critical incidents were found to act on behavior in two different ways: to support and confirm decision-making behavior (supportive critical incidents) or to alter behavior as to change or make an initial decision (behavior altering critical incidents). Comparing and contrasting populations' distinct pathways resulted in valuable discussion for recruitment and retention initiatives for the geoscience.

Literacy and students' interest on Geosciences - Findings and results of GEOschools project

NASA Astrophysics Data System (ADS)

Fermeli, Georgia; Steininger, Fritz; Dermitzakis, Michael; Meléndez, Guillermo; Page, Kevin

2014-05-01

GEOschools is a European project supported by the Lifelong Learning Programme. Among the main aims of the project were to investigate the interest secondary school students have on geosciences and the teaching strategies used. Also, the development of a guide for Geosciences Literacy at a European level (Fermeli et al., 2011). GEOschools' literacy framework proposal is based on a comparative analysis of geoscience curricula in the partner countries (Austria, Greece, Italy, Spain and Portugal). Results of an "Interest Research" survey involved around 1750 students and 60 teachers from partner countries, combined with specific proposals by the project partners (Calonge et al., 2011). Results of the GEOschools "Interest research" survey evidence students show a higher interest in those topics which have a potentially higher social impact, such as mass extinctions, dinosaurs, geological hazards and disasters and origin and evolution of life (including human evolution). These results provide an evidence base to justify why curriculum content and teaching strategies can be made more effective through focusing mainly on such "interest topics", instead of trying to follow an excessively rigid, or academic, development of teaching programs (Fermeli et al., 2013). GEOschools literacy framework is summarized in 14 separate chapters, each including a brief description of the main themes of each subject, the intended learning outcomes as well as keywords and a bibliography. More particularly, the chapters of the framework describe what students should know and do, and how they should relate, as European citizens, to the geosciences. To face the challenges of the present and the future, modern citizens should be literate in natural sciences and, within the context of the geosciences, be able to: • Demonstrate a knowledge and understanding of basic principles, models, laws and terminology of Geosciences. • Know how and where to find and access scientifically reliable information about Earth at a national and international level. • Recognize their responsibilities concerning geodiversity and Earth resources as responsible, world citizens. • Understand planet Earth as a system • Appreciate geodiversity and geoheritage as a key topic within local sustainable development programs. • Know how to predict and mitigate the impacts of natural hazards and evaluate the most appropriate corrective measures. • Demonstrate an ability to apply geoscientific knowledge in the real world and take appropriate decisions. • Describe and explain basic geoscientific phenomena, data and procedures in familiar and unfamiliar contexts. Finally, GEOschools project has proposed a series of teaching modules trying to build effective and enjoyable learning thorough good, academic teaching practice. In this way students should be able to develop a unique set of skills, combining geological knowledge with practical skills. Bibliography: Calonge, A. (2011). Curriculum comparison research: GEOschools programme, 7p. Available from http://geoschools.geol.uoa.gr/pdfs/FinalRemarksCvComparison_EN.pdf . Accessed 10 January 2014. Fermeli G., Meléndez G., Koutsouveli An., Dermitzakis M., Calonge A., Steininger F., D'Arpa C., Di Patti C. (2013).Geosciences' teaching and students' interest in secondary schools - Preliminary results from an interest research in Greece, Spain and Italy.Geoheritage, 14p. Available from http://link.springer.com/article/10.1007%2Fs12371-013-0094-4 . Accessed 10 January 2014.

Laboratory directed research and development. FY 1995 progress report

DOE Office of Scientific and Technical Information (OSTI.GOV)

Vigil, J.; Prono, J.

1996-03-01

This document presents an overview of Laboratory Directed Research and Development Programs at Los Alamos. The nine technical disciplines in which research is described include materials, engineering and base technologies, plasma, fluids, and particle beams, chemistry, mathematics and computational science, atmic and molecular physics, geoscience, space science, and astrophysics, nuclear and particle physics, and biosciences. Brief descriptions are provided in the above programs.

News and Views: A VISTA of the Orion Nebula; Grote Reber Award; Leverhulme Prize; GNSS workshop; Farming in space; Space messages

NASA Astrophysics Data System (ADS)

2010-04-01

The recipient of the 2010 Grote Reber Award is Dr Alan Rogers, a Research Affiliate at the Massachusetts Institute of Technology Haystack Observatory. Matt King, a Reader in Polar Geodesy in the School of Civil Engineering and Geosciences at the University of Newcastle, was awarded a Philip Leverhulme Prize in 2009.

The Virtual Geophysics Laboratory (VGL): Scientific Workflows Operating Across Organizations and Across Infrastructures

NASA Astrophysics Data System (ADS)

Cox, S. J.; Wyborn, L. A.; Fraser, R.; Rankine, T.; Woodcock, R.; Vote, J.; Evans, B.

2012-12-01

The Virtual Geophysics Laboratory (VGL) is web portal that provides geoscientists with an integrated online environment that: seamlessly accesses geophysical and geoscience data services from the AuScope national geoscience information infrastructure; loosely couples these data to a variety of gesocience software tools; and provides large scale processing facilities via cloud computing. VGL is a collaboration between CSIRO, Geoscience Australia, National Computational Infrastructure, Monash University, Australian National University and the University of Queensland. The VGL provides a distributed system whereby a user can enter an online virtual laboratory to seamlessly connect to OGC web services for geoscience data. The data is supplied in open standards formats using international standards like GeoSciML. A VGL user uses a web mapping interface to discover and filter the data sources using spatial and attribute filters to define a subset. Once the data is selected the user is not required to download the data. VGL collates the service query information for later in the processing workflow where it will be staged directly to the computing facilities. The combination of deferring data download and access to Cloud computing enables VGL users to access their data at higher resolutions and to undertake larger scale inversions, more complex models and simulations than their own local computing facilities might allow. Inside the Virtual Geophysics Laboratory, the user has access to a library of existing models, complete with exemplar workflows for specific scientific problems based on those models. For example, the user can load a geological model published by Geoscience Australia, apply a basic deformation workflow provided by a CSIRO scientist, and have it run in a scientific code from Monash. Finally the user can publish these results to share with a colleague or cite in a paper. This opens new opportunities for access and collaboration as all the resources (models, code, data, processing) are shared in the one virtual laboratory. VGL provides end users with access to an intuitive, user-centered interface that leverages cloud storage and cloud and cluster processing from both the research communities and commercial suppliers (e.g. Amazon). As the underlying data and information services are agnostic of the scientific domain, they can support many other data types. This fundamental characteristic results in a highly reusable virtual laboratory infrastructure that could also be used for example natural hazards, satellite processing, soil geochemistry, climate modeling, agriculture crop modeling.

STEM Education in Jordan Applicable to Developing Future Geophysicists: An Example Combining Electrical Engineering and Medical Research

NASA Astrophysics Data System (ADS)

Fraiwan, A.; Khadra, L.; Shahab, W.; Olgaard, D. L.

2010-12-01

Students in developing countries interested in STEM disciplines (science, technology, engineering & math) often choose majors that will improve their job opportunities in their home country when they graduate, e.g. engineering or medicine. Geoscience might be chosen as a sub-discipline of civil engineering, but rarely as a primary major unless there are local economic natural resources. The Institute of International Education administers the ExxonMobil Middle East and North Africa region scholars program designed to develop skilled students with a focus on geoscience and to build relationships with academic leaders by offering select faculty the opportunity to participation in the AGU fall meeting. At the Jordan University of Science and Technology (JUST), research in electrical engineering applied to medicine has potential links to geosciences. In geophysics, neural wavelet analysis (NWA) is commonly used to process complex seismic signals, e.g. for interpreting lithology or identifying hydrocarbons. In this study, NWA was used to characterize cardiac arrhythmias. A classification scheme was developed in which a neural network is used to identify three types of arrhythmia by distinct frequency bands. The performance of this scheme was tested using patient records from two electrocardiography (ECG) databases. These records contain normal ECG signals, as well as abnormal signals from atrial fibrillation (AF), ventricular tachycardia (VT) and ventricular fibrillation (VF) arrhythmias. The continuous wavelet transform is applied over frequencies of 0-50 Hz for times of 0-2s. For a normal ECG, the results show that the strongest signal is in a frequency range of 4-10 Hz. For AF, a low frequency ECG signal in the range of 0-5 Hz extends over the whole time domain. For VT, the low frequency spectrum is in the range of 2-10 Hz, appearing as three distinct bands. For VF, a continuous band in the range of 2-10 Hz extends over the whole time domain. The classification of the three arrhythmias used a Back-propagation neural network whose input is the energy level calculated from the wavelet transform. The network was trained using 13 different patterns (3 for AF, 5 for VT and 5 for VF) and blind tested on 25 records. The classification scheme correctly identified all 9 VF records, 5 of 6 VT records, and 9 of 10 AF records. Manual interpretation of time-frequency seismic data is computationally intensive because large volumes of data are generated during the time-frequency analysis process. The proposed NWA method has the potential to partially automate the interpretation of seismic data. Also, a relatively straight-forward adaptation of the proposed NWA-based classification scheme may help identify hydrocarbon-laden reservoirs, which have been observed to contain enhanced low-frequency content in the time-frequency domain (Castagna, Sun, & Siegfried, 2003).

Enabling Big Geoscience Data Analytics with a Cloud-Based, MapReduce-Enabled and Service-Oriented Workflow Framework

PubMed Central

Li, Zhenlong; Yang, Chaowei; Jin, Baoxuan; Yu, Manzhu; Liu, Kai; Sun, Min; Zhan, Matthew

2015-01-01

Geoscience observations and model simulations are generating vast amounts of multi-dimensional data. Effectively analyzing these data are essential for geoscience studies. However, the tasks are challenging for geoscientists because processing the massive amount of data is both computing and data intensive in that data analytics requires complex procedures and multiple tools. To tackle these challenges, a scientific workflow framework is proposed for big geoscience data analytics. In this framework techniques are proposed by leveraging cloud computing, MapReduce, and Service Oriented Architecture (SOA). Specifically, HBase is adopted for storing and managing big geoscience data across distributed computers. MapReduce-based algorithm framework is developed to support parallel processing of geoscience data. And service-oriented workflow architecture is built for supporting on-demand complex data analytics in the cloud environment. A proof-of-concept prototype tests the performance of the framework. Results show that this innovative framework significantly improves the efficiency of big geoscience data analytics by reducing the data processing time as well as simplifying data analytical procedures for geoscientists. PMID:25742012

Enabling big geoscience data analytics with a cloud-based, MapReduce-enabled and service-oriented workflow framework.

PubMed

Li, Zhenlong; Yang, Chaowei; Jin, Baoxuan; Yu, Manzhu; Liu, Kai; Sun, Min; Zhan, Matthew

2015-01-01

Geoscience observations and model simulations are generating vast amounts of multi-dimensional data. Effectively analyzing these data are essential for geoscience studies. However, the tasks are challenging for geoscientists because processing the massive amount of data is both computing and data intensive in that data analytics requires complex procedures and multiple tools. To tackle these challenges, a scientific workflow framework is proposed for big geoscience data analytics. In this framework techniques are proposed by leveraging cloud computing, MapReduce, and Service Oriented Architecture (SOA). Specifically, HBase is adopted for storing and managing big geoscience data across distributed computers. MapReduce-based algorithm framework is developed to support parallel processing of geoscience data. And service-oriented workflow architecture is built for supporting on-demand complex data analytics in the cloud environment. A proof-of-concept prototype tests the performance of the framework. Results show that this innovative framework significantly improves the efficiency of big geoscience data analytics by reducing the data processing time as well as simplifying data analytical procedures for geoscientists.

GeoSegmenter: A statistically learned Chinese word segmenter for the geoscience domain

NASA Astrophysics Data System (ADS)

Huang, Lan; Du, Youfu; Chen, Gongyang

2015-03-01

Unlike English, the Chinese language has no space between words. Segmenting texts into words, known as the Chinese word segmentation (CWS) problem, thus becomes a fundamental issue for processing Chinese documents and the first step in many text mining applications, including information retrieval, machine translation and knowledge acquisition. However, for the geoscience subject domain, the CWS problem remains unsolved. Although a generic segmenter can be applied to process geoscience documents, they lack the domain specific knowledge and consequently their segmentation accuracy drops dramatically. This motivated us to develop a segmenter specifically for the geoscience subject domain: the GeoSegmenter. We first proposed a generic two-step framework for domain specific CWS. Following this framework, we built GeoSegmenter using conditional random fields, a principled statistical framework for sequence learning. Specifically, GeoSegmenter first identifies general terms by using a generic baseline segmenter. Then it recognises geoscience terms by learning and applying a model that can transform the initial segmentation into the goal segmentation. Empirical experimental results on geoscience documents and benchmark datasets showed that GeoSegmenter could effectively recognise both geoscience terms and general terms.

Supercomputing resources empowering superstack with interactive and integrated systems

NASA Astrophysics Data System (ADS)

Rückemann, Claus-Peter

2012-09-01

This paper presents the results from the development and implementation of Superstack algorithms to be dynamically used with integrated systems and supercomputing resources. Processing of geophysical data, thus named geoprocessing, is an essential part of the analysis of geoscientific data. The theory of Superstack algorithms and the practical application on modern computing architectures was inspired by developments introduced with processing of seismic data on mainframes and within the last years leading to high end scientific computing applications. There are several stacking algorithms known but with low signal to noise ratio in seismic data the use of iterative algorithms like the Superstack can support analysis and interpretation. The new Superstack algorithms are in use with wave theory and optical phenomena on highly performant computing resources for huge data sets as well as for sophisticated application scenarios in geosciences and archaeology.