Assessing Current State Science Teaching and Learning Standards for Ability to Achieve Climate Science Literacy

NASA Astrophysics Data System (ADS)

Busch, K. C.

2012-12-01

Even though there exists a high degree of consensus among scientists about climate change, doubt has actually increased over the last five years within the general U.S. public. In 2006, 79% of those polled agreed that there is evidence for global warming, while only 59% agreed in 2010 (Pew Research Center, 2010). The source for this doubt can be partially attributed to lack of knowledge. Formal education is one mechanism that potentially can address inadequate public understanding as school is the primary place where students - and future citizens - learn about the climate. In a joint effort, several governmental agencies, non-governmental organizations, scientists and educators have created a framework called The Essential Principles of Climate Science Literacy, detailing seven concepts that are deemed vital for individuals and communities to understand Earth's climate system (USGCRP, 2009). Can students reach climate literacy - as defined by these 7 concepts - if they are taught using a curriculum based on the current state standards? To answer this question, the K-12 state science teaching and learning standards for Texas and California - two states that heavily influence nation-wide textbook creation - were compared against the Essential Principles. The data analysis consisted of two stages, looking for: 1) direct reference to "climate" and "climate change" and 2) indirect reference to the 7 Essential Principles through axial coding. The word "climate" appears in the California K-12 science standards 4 times and in the Texas standards 7 times. The word "climate change" appears in the California and Texas standards only 3 times each. Indirect references to the 7 Essential Principles of climate science literacy were more numerous. Broadly, California covered 6 of the principles while Texas covered all 7. In looking at the 7 principles, the second one "Climate is regulated by complex interactions among component of the Earth system" was the most substantively

Visualizing the Chemistry of Climate Change (VC3Chem): Online resources for teaching and learning chemistry through the rich context of climate science

NASA Astrophysics Data System (ADS)

McKenzie, L.; Versprille, A.; Towns, M.; Mahaffy, P.; Martin, B.; Kirchhoff, M.

2013-12-01

Global climate change is one of the most pressing environmental challenges facing humanity. Many of the important underlying concepts require mental models that are built on a fundamental understanding of chemistry, yet connections to climate science and global climate change are largely missing from undergraduate chemistry courses for science majors. In Visualizing the Chemistry of Climate Change (VC3Chem), we have developed and piloted a set of online modules that addresses this gap by teaching core chemistry concepts through the rich context of climate science. These interactive web-based digital learning experiences enable students to learn about isotopes and their relevance in determining historical temperature records, IR absorption by greenhouse gases, and acid/base chemistry and the impacts on changing ocean pH. The efficacy of these tools and this approach has been assessed through measuring changes in students' understanding about both climate change and core chemistry concepts.

A Culturally Relevant Teacher Professional Development for Teaching Climate Change to Native American Students

ERIC Educational Resources Information Center

Kern, Anne Liu; Honwad, Sameer; McLain, Ed

2017-01-01

The science of climate change is a complex subject to teach. Teachers find climate change a challenging topic to teach due to a myriad of reasons. Gayford, 2010 describes some of the challenges teachers face while teaching climate change science as "first, the controversial nature of the topic; second, it does not relate well to the normal…

Teaching climate science within the transdisciplinary framework of Critical Zone science

NASA Astrophysics Data System (ADS)

White, T. S.; Wymore, A.; Dere, A. L. D.; Washburne, J. C.; Hoffman, A.; Conklin, M. H.

2017-12-01

During the past decade a new realm of Earth surface and environmental science has evolved, Critical Zone (CZ) science. The CZ is the outermost layer of the continents spanning from the top of the vegetation canopy down to the bottom of the fresh groundwater zone. CZ science integrates across many disciplines and cross cutting concepts, including climate science, and much progress has been made by the CZ community to develop educational curricula - descriptions of the climate science aspects of two of those follows. An interdisciplinary team of CZ scientists developed an undergraduate course entitled "Introduction to CZ science". The semester-long course is modular, has been tested in multiple university settings, and the content is available online. A primary tenet of the course is that to achieve environmental sustainability, society must understand the CZ system, the natural processes and services of the CZ that are of value to society, and how those processes operate with and without the presence of humanity. A fundamental concept in the course is that the fluxes of water, C, energy, reactive gases, particulates and nutrients throughout the CZ are directly and indirectly related to climatic phenomenon and processes. Units on land-atmosphere interactions, weathering, and water budgets highlight the connection between CZ science and climate science, and are augmented by learning activities that consider climate links to soil development and landscape evolution. An online open-source course entitled "Earth 530: Earth Surface Processes in the Critical Zone'" is offered as part of The Pennsylvania State University's Masters of Education in Earth Sciences program. The course is designed to educate teachers interested in incorporating CZ science into their classrooms, though it is usable by anyone with a basic understanding of Earth surface and environmental science. Earth 530 introduces students to knowledge needed to understand the CZ through integration of

Emotions in teaching environmental science

NASA Astrophysics Data System (ADS)

Quigley, Cassie

2016-09-01

This op-ed article examines the emotional impact of teaching environmental science and considers how certain emotions can broaden viewpoints and other emotions narrow them. Specifically, it investigates how the topic of climate change became an emotional debate in a science classroom because of religious beliefs. Through reflective practice and examination of positionality, the author explored how certain teaching practices of pre-service science teachers created a productive space and other practices closed down the conversations. This article is framed with theories that explore both divergent and shared viewpoints.

Perceptions and Practices of Culturally Relevant Science Teaching in American Indian Classrooms

ERIC Educational Resources Information Center

Nam, Younkyeong; Roehrig, Gillian; Kern, Anne; Reynolds, Bree

2013-01-01

This study explores the perceptions of culturally relevant science teaching of 35 teachers of American Indian students. These teachers participated in professional development designed to help them better understand climate change science content and teaching climate change using both Western science and traditional and cultural knowledge. Teacher…

Meteorological stations as a tool to teach on climate system sciences

NASA Astrophysics Data System (ADS)

Cerdà, Artemi; Bodí, Merche B.; Damián Ruiz-Sinoga, José

2010-05-01

Higher education has been focussed on teaching climate system theory. Meteorology and climatology student rarely visited a meteorological station. However, meteorological stations are the source of information for the climate system studies and they supply the key information for modelling. This paper shows how meteorological station is a key tool to introduce student to the study of climate and meteorology. The research stations of Montesa and El Teularet-Sierra de Enguera are being used for seven years to supply data to the students of Climatology, 1st year of the Degree in Geography at the University of Valencia. The results show that the students that used the raw data set were proud to use original data. Those students got higher qualifications and they choose also in the following year courses on climatology or Physical Geography. Then, the conclusions are that the use of meteorological stations is a positive contribution to the improvement of the knowledge of the students, and his compromise with the science and the environment.

Addressing climate and energy misconceptions - teaching tools offered by the Climate Literacy and Energy Awareness Network (CLEAN)

NASA Astrophysics Data System (ADS)

Gold, A. U.; Ledley, T. S.; Kirk, K. B.; Grogan, M.; McCaffrey, M. S.; Buhr, S. M.; Manduca, C. A.; Fox, S.; Niepold, F.; Howell, C.; Lynds, S. E.

2011-12-01

Despite a prevalence of peer-reviewed scientific research and high-level reports by intergovernmental agencies (e.g., IPCC) that document changes in our climate and consequences for human societies, the public discourse regards these topics as controversial and sensitive. The chasm between scientific-based understanding of climate systems and public understanding can most easily be addressed via high quality, science-based education on these topics. Well-trained and confident educators are required to provide this education. However, climate science and energy awareness are complex topics that are rapidly evolving and have a great potential for controversy. Furthermore, the interdisciplinary nature of climate science further increases the difficulty for teachers to stay abreast of the science and the policy. Research has shown that students and educators alike hold misconceptions about the climate system in general and the causes and effects of climate change in particular. The NSF-funded CLEAN Pathway (http://cleanet.org) as part of the National Science Digital Library (http://www.nsdl.org) strives to address these needs and help educators address misconceptions by providing high quality learning resources and professional development opportunities to support educators of grade levels 6 through 16. The materials focus on teaching climate science and energy use. The scope and framework of the CLEAN Pathway is defined by the Essential Principles of Climate Science (CCSP, 2009) and the Energy Literacy Principles recently developed by the Department of Energy. Following this literacy-based approach, CLEAN helps with developing mental models to address misconceptions around climate science and energy awareness through a number of different avenues. These are: 1) Professional development opportunities for educators - interactive webinars for secondary teachers and virtual workshops for college faculty, 2) A collection of scientifically and pedagogically reviewed, high

Inspiring Inquiry: Scientists, science teachers, and GK-12 students learning climate science together

NASA Astrophysics Data System (ADS)

Stwertka, C.; Blonquist, J.; Feener, D.

2010-12-01

A major communication gap exists between climate scientists, educators, and society. As a result, findings from climate research, potential implications of climate change, and possible mitigation strategies are not fully understood and accepted outside of the climate science community. A good way to begin bridging the gap is to teach climate science to students in public schools. TGLL (Think Globally, Learn Locally) is an NSF GK-12 program based at the University of Utah, which partners graduate students in the biological, geological and atmospheric sciences with middle and high school teachers in the Salt Lake City School District to improve the communication skills of Fellows and enhance inquiry-based science teaching and learning in the classroom. Each TGLL Fellow works in the same classroom(s) throughout the year, developing his or her scientific communication skills while providing teachers with content knowledge, resources, classroom support, and enhancing the experience of students such that science becomes an interesting and accessible tool for acquiring knowledge. The TGLL Fellows work closely as a group to develop inquiry-based teaching modules (a series of lessons) and a field trip that involve students in doing authentic science. Lessons are designed to apply national and Utah core curriculum concepts to broader scientific issues such as habitat alteration, pollution and disturbance, invasive species, and infectious disease, with the focus of the 2010-2011 school year being climate change. The TGLL Global Climate Change module contains lesson plans on climate temporal and spatial scales, temperature variation, energy balance, the carbon cycle, the greenhouse effect, climate feedback loops, anthropogenic climate change indicators, climate change consequences and impacts, and actions students can take to reduce greenhouse gas emissions. The capstone experience for the module is a “Backyard Climate Change” field trip to a local pristine canyon

Exploring students' epistemological knowledge of models and modelling in science: results from a teaching/learning experience on climate change

NASA Astrophysics Data System (ADS)

Tasquier, Giulia; Levrini, Olivia; Dillon, Justin

2016-03-01

The scientific community has been debating climate change for over two decades. In the light of certain arguments put forward by the aforesaid community, the EU has recommended a set of innovative reforms to science teaching such as incorporating environmental issues into the scientific curriculum, thereby helping to make schools a place of civic education. However, despite these European recommendations, relatively little emphasis is still given to climate change within science curricula. Climate change, although potentially engaging for students, is a complex topic that poses conceptual difficulties and emotional barriers, as well as epistemological challenges. Whilst the conceptual and emotional barriers have already been the object of several studies, students' reactions to the epistemological issues raised by climate changes have so far been rarely explored in science education research and thus are the main focus of this paper. This paper describes a study concerning the implementation of teaching materials designed to focus on the epistemological role of 'models and the game of modelling' in science and particularly when dealing with climate change. The materials were implemented in a course of 15 hours (five 3-hour lessons) for a class of Italian secondary-school students (grade 11; 16-17 years old). The purpose of the study is to investigate students' reactions to the epistemological dimension of the materials, and to explore if and how the material enabled them to develop their epistemological knowledge on models.

Preparing Middle School Teachers to Use Science Models Effectively when Teaching about Weather and Climate Topics

NASA Astrophysics Data System (ADS)

Yarker, M. B.; Stanier, C. O.; Forbes, C.; Park, S.

2012-12-01

According to the National Science Education Standards (NSES), teachers are encouraged to use science models in the classroom as a way to aid in the understanding of the nature of the scientific process. This is of particular importance to the atmospheric science community because climate and weather models are very important when it comes to understanding current and future behaviors of our atmosphere. Although familiar with weather forecasts on television and the Internet, most people do not understand the process of using computer models to generate weather and climate forecasts. As a result, the public often misunderstands claims scientists make about their daily weather as well as the state of climate change. Therefore, it makes sense that recent research in science education indicates that scientific models and modeling should be a topic covered in K-12 classrooms as part of a comprehensive science curriculum. The purpose of this research study is to describe how three middle school teachers use science models to teach about topics in climate and weather, as well as the challenges they face incorporating models effectively into the classroom. Participants in this study took part in a week long professional development designed to orient them towards appropriate use of science models for a unit on weather, climate, and energy concepts. The course design was based on empirically tested features of effective professional development for science teachers and was aimed at teaching content to the teachers while simultaneously orienting them towards effective use of science models in the classroom in a way that both aids in learning about the content knowledge as well as how models are used in scientific inquiry. Results indicate that teachers perceive models to be physical representations that can be used as evidence to convince students that the teacher's conception of the concept is correct. Additionally, teachers tended to use them as ways to explain an idea to

Adapting to Teach Climate Literacy

NASA Astrophysics Data System (ADS)

Wilkening, B.; Schwartz, K. L.

2017-12-01

Adaptation is a key strategy to deal with the effects of climate change, and it can also be a key strategy in teaching climate literacy. Adapting curriculum to include utilizing new instructional practices, modifying existing lessons, evaluating evidence and engaging students in real-world projects are strategies employed in Recharge the Rain. Arizona Project WET and Watershed Management Group developed the Recharge the Rain project, through a NOAA Environmental Literacy Grant, to build community resiliency to hazards associated with increased temperatures, drought and flooding in Arizona. Sixth through twelfth grade teachers, students and the public will move through a continuum from awareness, to knowledge gain, to conceptual understanding, to action. During the first year of the project, through professional development and ongoing guidance, teachers developed a climate literacy curriculum to use in their classrooms. Using systems thinking language and structure from the Cabrera Research Labs, teachers and students gain the thinking tools necessary to increase understanding of Earth's climate system. Lessons and resources for teaching about climate change are abundant and many, such as those on the Climate Literacy Education Awareness Network (CLEAN), have gone through an extensive review process. By cataloguing online resources and sharing these with teachers through a social bookmarking tool, wakelet.com, teachers are easily able to find appropriate teaching material. Engaging students in evaluating evidence requires the data to be relevant to their everyday lives. Online data resources are readily available from NOAA and other sources at both the global and local levels. When teachers, students and the public contribute to the data collection process in citizen science projects such as CoCoRaHS, iSeeChange, and USA National Phenology Network, the data empowers them to act in ways to mitigate the climate threats in their community. Adapting to teach climate

Innovating Science Teaching by Participatory Action Research--Reflections from an Interdisciplinary Project of Curriculum Innovation on Teaching about Climate Change

ERIC Educational Resources Information Center

Feierabend, Timo; Eilks, Ingo

2011-01-01

This paper describes a three-year curriculum innovation project on teaching about climate change. The innovation for this study focused on a socio-critical approach towards teaching climate change in four different teaching domains (biology, chemistry, physics and politics). The teaching itself explicitly aimed at general educational objectives,…

Exploring Small Climates--An Outdoor Science Technique.

ERIC Educational Resources Information Center

Rillo, Thomas J.

The study of climates in small areas as an outdoor science teaching technique is described in this paper. It is suggested that, while teachers are presenting a weather unit to their elementary school classes, they should not overlook the opportunity to make learning more meaningful through outdoor teaching techniques. Explorations of temperatures…

Story - Science - Solutions: A new middle school science curriculum that promotes climate-stewardship

NASA Astrophysics Data System (ADS)

Cordero, E.; Centeno Delgado, D. C.

2017-12-01

Over the last five years, Green Ninja has been developing educational media to help motivate student interest and engagement around climate science and solutions. The adoption of the Next Generation Science Standards (NGSS) offers a unique opportunity where schools are changing both what they teach in a science class and how they teach. Inspired by the new emphasis in NGSS on climate change, human impact and engineering design, Green Ninja developed a technology focused, integrative, and yearlong science curriculum (6th, 7th and 8th grade) focused broadly around solutions to environmental problems. The use of technology supports the development of skills valuable for students, while also offering real-time metrics to help measure both student learning and environmental impact of student actions. During the presentation, we will describe the design philosophy around our middle school curriculum and share data from a series of classes that have created environmental benefits that transcend the traditional classroom. The notion that formal education, if done correctly, can be leveraged as a viable climate mitigation strategy will be discussed.

Collaborative Education in Climate Change Sciences and Adaptation through Interactive Learning

NASA Astrophysics Data System (ADS)

Ozbay, G.; Sriharan, S.; Fan, C.

2014-12-01

As a result of several funded climate change education grants, collaboration between VSU, DSU, and MSU, was established to provide the innovative and cohesive education and research opportunities to underrepresented groups in the climate related sciences. Prior to offering climate change and adaptation related topics to the students, faculty members of the three collaborating institutions participated at a number of faculty training and preparation workshops for teaching climate change sciences (i.e. AMS Diversity Project Workshop, NCAR Faculty-Student Team on Climate Change, NASA-NICE Program). In order to enhance the teaching and student learning on various issues in the Environmental Sciences Programs, Climatology, Climate Change Sciences and Adaptation or related courses were developed at Delaware State University and its partner institutions (Virginia State University and Morgan State University). These courses were prepared to deliver information on physical basis for the earth's climate system and current climate change instruction modules by AMS and historic climate information (NOAA Climate Services, U.S. and World Weather Data, NCAR and NASA Climate Models). By using Global Seminar as a Model, faculty members worked in teams to engage students in videoconferencing on climate change through Contemporary Global Studies and climate courses including Climate Change and Adaptation Science, Sustainable Agriculture, Introduction to Environmental Sciences, Climatology, and Ecology and Adaptation courses. All climate change courses have extensive hands-on practices and research integrated into the student learning experiences. Some of these students have presented their classroom projects during Earth Day, Student Climate Change Symposium, Undergraduate Summer Symposium, and other national conferences.

The Teaching of Anthropogenic Climate Change and Earth Science via Technology-Enabled Inquiry Education

NASA Technical Reports Server (NTRS)

Bush, Drew; Sieber, Renee; Seiler, Gale; Chandler, Mark

2016-01-01

A gap has existed between the tools and processes of scientists working on anthropogenic global climate change (AGCC) and the technologies and curricula available to educators teaching the subject through student inquiry. Designing realistic scientific inquiry into AGCC poses a challenge because research on it relies on complex computer models, globally distributed data sets, and complex laboratory and data collection procedures. Here we examine efforts by the scientific community and educational researchers to design new curricula and technology that close this gap and impart robust AGCC and Earth Science understanding. We find technology-based teaching shows promise in promoting robust AGCC understandings if associated curricula address mitigating factors such as time constraints in incorporating technology and the need to support teachers implementing AGCC and Earth Science inquiry. We recommend the scientific community continue to collaborate with educational researchers to focus on developing those inquiry technologies and curricula that use realistic scientific processes from AGCC research and/or the methods for determining how human society should respond to global change.

Climate Change Education Today in K-12: What's Happening in the Earth and Space Science Classroom?

NASA Astrophysics Data System (ADS)

Holzer, M. A.; National Earth Science Teachers Association

2011-12-01

Climate change is a highly interdisciplinary topic, involving not only multiple fields of science, but also social science and the humanities. There are many aspects of climate change science that make it particularly well-suited for exploration in the K-12 setting, including opportunities to explore the unifying processes of science such as complex systems, models, observations, change and evolution. Furthermore, this field of science offers the opportunity to observe the nature of science in action - including how scientists develop and improve their understanding through research and debate. Finally, climate change is inherently highly relevant to students - indeed, students today will need to deal with the consequences of the climate change. The science of climate change is clearly present in current science education standards, both at the National level as well as in the majority of states. Nonetheless, a significant number of teachers across the country report difficulties addressing climate change in the classroom. The National Earth Science Teachers Association has conducted several surveys of Earth and space science educators across the country over the past several years on a number of issues, including their needs and concerns, including their experience of external influences on what they teach. While the number of teachers that report external pressures to not teach climate change science are in the minority (and less than the pressure to not teach evolution and related topics), our results suggest that this pressure against climate change science in the K-12 classroom has grown over the past several years. Some teachers report being threatened by parents, being encouraged by administrators to not teach the subject, and a belief that the "two sides" of climate change should be taught. Survey results indicate that teachers in religious or politically-conservative districts are more likely to report difficulties in teaching about climate change than in

Supporting Climate Literacy in the K12 Classroom by Identifying Educators' Perceived Barriers to and Gaps in Resources for Teaching Climate Change

NASA Astrophysics Data System (ADS)

Tayne, K.

2015-12-01

As K12 teachers seek ways to provide meaningful learning opportunities for students to understand climate change, they often face barriers to teaching about climate and/or lack relevant resources on the topic. In an effort to better understand how to support K12 teachers in this role, a survey about "teaching climate change" was created and distributed. The results of the 2015 survey are presented, based on more than 200 teacher responses. Respondents included National Science Teachers Association (NSTA) members, 2015 STEM Teacher and Researcher (STAR) Fellows and science teachers from several U.S. school districts. The survey identifies teachers' perceived barriers to teaching climate change, for example difficulty integrating climate change concepts into specific core courses (i.e., biology), as well as desired classroom resources, such as climate change project-based learning (PBL) units that connect to the Next Generation Science Standards (NGSS). Survey results also indicate possible pathways for federal agencies, non-profits, universities and other organizations to have a more significant impact on climate literacy in the classroom. In response to the survey results, a comprehensive guide is being created to teach climate change in K12 classrooms, addressing barriers and providing resources for teachers. For example, in the survey, some teachers indicated that they lacked confidence in their content knowledge and understanding of climate change, so this guide provides web-based resources to help further an educator's understanding of climate change, as well as opportunities for relevant online and in-person professional development. In this quest for desired resources to teach climate change, gaps in accessible and available online resources are being identified. Information about these "gaps" may help organizations that strive to support climate literacy in the classroom better serve teachers.

Teaching to the Next Generation Science Standards with Energy, Climate, and Water Focused Games

NASA Astrophysics Data System (ADS)

Mayhew, M. A.; Hall, M.; Civjan, N.

2015-12-01

We produced two fun-to-play card games with the theme, The Nexus of Energy, Water, and Climate, that directly support teaching to the NGSS. In the games, players come to understand how demand for energy, water use, and climate change are tightly intertwined. Analysis by scientists from the national laboratories ensured that the games are reflect current data and research. The games have been tested with high school and informal science educators and their students and have received a formal evaluation. The games website http://isenm.org/games-for-learning shows how the games align with the NGSS, the Common Core, and the NRC's Strands of Science Learning. It also contains an extensive collection of accessible articles on the nexus to support use of the games in instruction. Thirst for Power is a challenging resource management game. Players, acting as governors of regions, compete to be the first to meet their citizens' energy needs. A governor can choose from a variety of carbon-based or renewable energy sources, but each source uses water and has an environmental—including climate change—impact. Energy needs must be met using only the water resources allocated to the region and without exceeding the environmental impact limit. "ACTION" cards alter game play and increase competition. Challenge and Persuade is a game of scientific argumentation, using evidence on nexus-related fact cards. Players must evaluate information, develop fact-based arguments, and communicate their findings. One card deck contains a set of adjectives, a second a series of fact cards. Players use their fact cards to make the best argument that aligns with an adjective selected by the "Judge". Players take turns being the "Judge," who determines who made the best argument. The games particularly align with NGSS elements: Connections to Engineering, Technology, and Application of Science. Players come to understand the science and engineering behind many energy sources and their impacts

A Model for Teaching a Climate Change Elective Science Course at the Community College Level

NASA Astrophysics Data System (ADS)

Mandia, S. A.

2012-12-01

The impact of global climate change is far-reaching, both for humanity and for the environment. It is essential that our students be provided a strong scientific background for the role of natural and human caused climate change so that they are better prepared to become involved in the discussion. Here the author reveals a successful model designed for use with a diverse student body at the community college level. Teaching strategies beyond the traditional lecture and exam style include: web-based resources such as static websites along with dynamic blogging tools, post-lecture cooperative learning review sessions, weekly current event research projects, use of rubrics to assist students in their own project evaluation before submission, and a research paper utilizing the Skeptical Science website to examine the validity of the most common climate change myths.

Mock climate summit: teaching and assessing learning

NASA Astrophysics Data System (ADS)

Schweizer, D.; Gautier, C.; Bazerman, C.

2003-04-01

This paper will demonstrate the effectiveness of a Mock Climate Summit as a pedagogical approach for teaching the science and policy aspects of global climate change. The Mock Climate Summit is a student-centered course simulating the Conference of the Parties (COP) where international environmental protocols are negotiated. Compared to traditional lecture-based methods common in the geoscience classroom, the Mock Climate Summit uses negotiations and arguments to teach the interactions between these two “spheres” and demonstrate the depth and breadth of these interactions. Through a detailed assessment of students’ dialogue transcribed from video and audio tapes, we found that the nature of the student dialogue matures rapidly as they are given multiple opportunities to present, negotiate and argue a specific topic. Students’ dialogue progress from hypothetical (what-if) scenarios to action-oriented scenarios and implementation plans. The progression of the students’ dialogue shows increased comfort with the communities’ discourse as they take ownership of the point-of-view associated with their assumed roles.

Mock Climate Summit: Teaching and Assessing Learning

NASA Astrophysics Data System (ADS)

Schweizer, D.; Gautier, C.; Bazerman, C.

2003-04-01

This paper will demonstrate the effectiveness of a Mock Climate Summit as a pedagogical for teaching the science and policy aspects of global climate change. The Mock Climate Summit is a student-centered course simulating the Conference of the Parties (COP) where international environmental protocols are negotiated. Compared to traditional lecture-based methods common in the geoscience classroom, the Mock Climate Summit uses negotiations and arguments to teach the interactions between these two "spheres" and demonstrate the depth and breadth of these interactions. Through a detailed assessment of students' dialogue transcribed from video and audio tapes, we found that the nature of the student dialogue matures rapidly as they are given multiple opportunities to present, negotiate and argue a specific topic. Students' dialogue progress from hypothetical (what-if) scenarios to action-oriented scenarios and implementation plans. The progression of the students' dialogue shows increased comfort with the communities' discourse as they take ownership of the point-of-view associated with their assumed roles.

Improve Climate Change Literacy At Minority Institutions Through Problem-based Teaching And Learning

NASA Astrophysics Data System (ADS)

yang, Z.; Williams, H.

2013-12-01

Climate change is one of most popular topics in the U.S. Currently we are implementing our funded NASA climate change education grant entitled as 'Preparing Science Educators with Climate Change Literacy through Problem-based Teaching and Learning'. This project aims to prepare underrepresented STEM (Science, Technology, Engineering and Mathematics) teachers that are competent for teaching the contents of the Earth, climate, and climate change. In this project, we first developed lectures, assignments, and lab exercises which are related to climate change and then applied those materials in courses which are usually selected by pre-service teachers after modification based on students' evaluation. Also field visits to sites such as landfill and hog farm were provided to North Carolina Central University (NCCU) students in order to help them have better understanding on sources and amount of greenhouse gases emitted from human activities. In addition, summer interns are specifically trained to enhance and improve their knowledge and skills in climate change science. Those strategies have effectively improved climate change literacy of pre-service teachers at NCCU in spite of some challenges.

Promoting Climate And Data Literacy: University Courses Engaging Students In Effective Teaching, Learning, Communication And Outreach Practices.

NASA Astrophysics Data System (ADS)

Halversen, C.; McDonnell, J. D.; Apple, J. K.; Weiss, E. L.

2016-02-01

Two university courses, 1) Promoting Climate Literacy and 2) Climate and Data Literacy, developed by the University of California Berkeley provide faculty across the country with course materials to help their students delve into the science underlying global environmental change. The courses include culturally responsive content, such as indigenous and place-based knowledge, and examine how people learn and consequently, how we should teach and communicate science. Promoting Climate Literacy was developed working with Scripps Institution of Oceanography, University of Washington, and Western Washington University. Climate and Data Literacy was developed with Rutgers University and Padilla Bay National Estuarine Research Reserve, WA. The Climate and Data Literacy course also focuses on helping students in science majors participating in U-Teach programs and students in pre-service teacher education programs gain skills in using real and near-real time data through engaging in investigations using web-based and locally-relevant data resources. The course helps these students understand and apply the scientific practices, disciplinary concepts and big ideas described in the Framework for K-12 Science Education and the Next Generation Science Standards (NGSS). This course focuses on students interested in teaching middle school science for three reasons: (1) teachers often have relatively weak understandings of the practices of science, and of complex Earth systems science and climate change; (2) the concepts that underlie climate change align well with the NGSS; and (3) middle school is a critical time for promoting student interest in science and for recruitment to STEM careers and lifelong climate literacy. This course is now being field tested in a number of U-Teach programs including Florida State University, Louisiana State University, as well as pre-service teacher education programs at California State University East Bay, and Western Washington University

The Challenges and Success of Implementing Climate Studies Lessons for Pre-Professional Teachers at a Small Historically Black College to Engage Student Teaching of Science Pedagogy and Content Skill Based Learning.

NASA Astrophysics Data System (ADS)

Arnold, J.; Wider-Lewis, F.; Miller-Jenkins, A.

2017-12-01

This poster is a description of the challenges and success of implementing climate studies lessons for pre-service teachers to engage student teaching pedagogy and content skill based learning. Edward Waters College is a historical black college with an elementary education teacher program focused on urban elementary school teaching and learning. Pre-Service Elementary Educator Students often have difficulty with science and mathematics content and pedagogy. This poster will highlight the barriers and successes of using climate studies lessons to develop and enhance pre-service teachers' knowledge of elementary science principles particularly related to climate studies, physical and earth space science.

Downscaling Climate Science to the Classroom: Diverse Opportunities for Teaching Climate Science in Diverse Ways to Diverse Undergraduate Populations

NASA Astrophysics Data System (ADS)

Jones, R. M.; Gill, T. E.; Quesada, D.; Hedquist, B. C.

2015-12-01

Climate literacy and climate education are important topics in current socio-political debate. Despite numerous scientific findings supporting global climate changes and accelerated greenhouse warming, there is a social inertia resisting and slowing the rate at which many of our students understand and absorb these facts. A variety of reasons, including: socio-economic interests, political and ideological biases, misinformation from mass media, inappropriate preparation of science teachers, and lack of numancy have created serious challenges for public awareness of such an important issue. Different agencies and organizations (NASA, NOAA, EPA, AGU, APS, AMS and others) have created training programs for educators, not involved directly in climatology research, in order to learn climate science in a consistent way and then communicate it to the public and students. Different approaches on how to deliver such information to undergraduate students in diverse environments is discussed based on the author's experiences working in different minority-serving institutions across the nation and who have attended AMS Weather and Climate Studies training workshops, MSI-REACH, and the School of Ice. Different parameters are included in the analysis: demographics of students, size of the institutions, geographical locations, target audience, programs students are enrolled in, conceptual units covered, and availability of climate-related courses in the curricula. Additionally, the feasibility of incorporating a laboratory and quantitative analysis is analyzed. As a result of these comparisons it seems that downscaling of climate education experiences do not always work as expected in every institution regardless of the student body demographics. Different geographical areas, student body characteristics and type of institution determine the approach to be adopted as well as the feasibility to introduce different components for weather and climate studies. Some ideas are shared

Teaching climate change in undergraduate courses

NASA Astrophysics Data System (ADS)

Sadler, Michael

2013-04-01

Although anthropogenic climate change is generally accepted in the scientific community, there is considerable skepticism among the general population and, therefore, in undergraduate students of all majors. Students are often asked by their peers, family members, and others, whether they ``believe'' climate change is occurring and what should be done about it (if anything). I will present my experiences and recommendations for teaching the physics of climate change to both physics and non-science majors. For non-science majors, the basic approach is to try to develop an appreciation for the scientific method (particularly peer-reviewed research) in a course on energy and the environment. For physics majors, the pertinent material is normally covered in their undergraduate courses in modern physics and thermodynamics. Nevertheless, it helps to review the basics, e.g. introductory quantum mechanics (discrete energy levels of atomic systems), molecular spectroscopy, and blackbody radiation. I have done this in a separate elective topics course, titled ``Physics of Climate Change,'' to help the students see how their knowledge gives them insight into a topic that is very volatile (socially and politically).

Learning to teach effectively: Science, technology, engineering, and mathematics graduate teaching assistants' teaching self-efficacy

NASA Astrophysics Data System (ADS)

Dechenne, Sue Ellen

Graduate teaching assistants (GTAs) from science, technology, engineering, and mathematics (STEM) are important in the teaching of undergraduate students (Golde & Dore, 2001). However, they are often poorly prepared for teaching (Luft, Kurdziel, Roehrig, & Turner, 2004). This dissertation addresses teaching effectiveness in three related manuscripts: (1) A position paper that summarizes the current research on and develops a model of GTA teaching effectiveness. (2) An adaptation and validation of two instruments; GTA perception of teaching training and STEM GTA teaching self-efficacy. (3) A model test of factors that predict STEM GTA teaching self-efficacy. Together these three papers address key questions in the understanding of teaching effectiveness in STEM GTAs including: (a) What is our current knowledge of factors that affect the teaching effectiveness of GTAs? (b) Given that teaching self-efficacy is strongly linked to teaching performance, how can we measure STEM GTAs teaching self-efficacy? (c) Is there a better way to measure GTA teaching training than currently exists? (d) What factors predict STEM GTA teaching self-efficacy? An original model for GTA teaching effectiveness was developed from a thorough search of the GTA teaching literature. The two instruments---perception of training and teaching self-efficacy---were tested through self-report surveys using STEM GTAs from six different universities including Oregon State University (OSU). The data was analyzed using exploratory and confirmatory factor analysis. Using GTAs from the OSU colleges of science and engineering, the model of sources of STEM GTA teaching self-efficacy was tested by administering self-report surveys and analyzed by using OLS regression analysis. Language and cultural proficiency, departmental teaching climate, teaching self-efficacy, GTA training, and teaching experience affect GTA teaching effectiveness. GTA teaching self-efficacy is a second-order factor combined from self

Exploring Students' Epistemological Knowledge of Models and Modelling in Science: Results from a Teaching/Learning Experience on Climate Change

ERIC Educational Resources Information Center

Tasquier, Giulia; Levrini, Olivia; Dillon, Justin

2016-01-01

The scientific community has been debating climate change for over two decades. In the light of certain arguments put forward by the aforesaid community, the EU has recommended a set of innovative reforms to science teaching such as incorporating environmental issues into the scientific curriculum, thereby helping to make schools a place of civic…

Teaching with Moodle in Soil Science

NASA Astrophysics Data System (ADS)

Roca, Núria

2014-05-01

Soil is a 3-dimensional body with properties that reflect the impact of climate, vegetation, fauna, man and topography on the soil's parent material over a variable time span. Therefore, soil is integral to many ecological and social systems and it holds potential solutions for many of the world's economic and scientific problems as climate change or scarcity of food and water. The teaching of Soil Science, as a natural science in its own right, requires principles that reflect the unique features and behaviour of soil and the practices of soil scientists. It could be argued that a unique set of teaching practices applies to Soil Science; however specific teaching practices are scarce in literature. The present work was triggered by the need to develop new techniques of teaching to speed up the learning process and to experiment with new methods of teaching. For such, it is necessary to adopt virtual learning environment to new learning requirements regarding Soil Science. This paper proposes a set of e-teaching techniques (as questionnaires, chats as well as forums) introduced in Moodle virtual learning Environment in order to increase student motivation and interest in Soil Science. Such technologies can be used to: a)Increase the amount of time a teacher allots for student reflection after asking a question and before a student responds (wait-time). This practice increases the quantity and quality of students' answers. The students give longer responses, students give more evidence for their ideas and conclusions, students speculate and hypothesize more and more students participated in responding. Furthermore, students ask more questions and talk more to other students. b)Improve active learning, an essential paradigm in education. In contrast to learning-before-doing, we propose to focus on learning-in-doing, a model where learners are increasingly involved in the authentic practices of communities through learning conversations and activities involving expert

Constructivist Learning Theory and Climate Science Communication

NASA Astrophysics Data System (ADS)

Somerville, R. C.

2012-12-01

Communicating climate science is a form of education. A scientist giving a television interview or testifying before Congress is engaged in an educational activity, though one not identical to teaching graduate students. Knowledge, including knowledge about climate science, should never be communicated as a mere catalogue of facts. Science is a process, a way of regarding the natural world, and a fascinating human activity. A great deal is already known about how to do a better job of science communication, but implementing change is not easy. I am confident that improving climate science communication will involve the paradigm of constructivist learning theory, which traces its roots to the 20th-century Swiss epistemologist Jean Piaget, among others. This theory emphasizes the role of the teacher as supportive facilitator rather than didactic lecturer, "a guide on the side, not a sage on the stage." It also stresses the importance of the teacher making a serious effort to understand and appreciate the prior knowledge and viewpoint of the student, recognizing that students' minds are not empty vessels to be filled or blank slates to be written on. Instead, students come to class with a background of life experiences and a body of existing knowledge, of varying degrees of correctness or accuracy, about almost any topic. Effective communication is also usually a conversation rather than a monologue. We know too that for many audiences, the most trusted messengers are those who share the worldview and cultural values of those with whom they are communicating. Constructivist teaching methods stress making use of the parallels between learning and scientific research, such as the analogies between assessing prior knowledge of the audience and surveying scientific literature for a research project. Meanwhile, a well-funded and effective professional disinformation campaign has been successful in sowing confusion, and as a result, many people mistakenly think climate

Using Data from Climate Science to Teach Introductory Statistics

ERIC Educational Resources Information Center

Witt, Gary

2013-01-01

This paper shows how the application of simple statistical methods can reveal to students important insights from climate data. While the popular press is filled with contradictory opinions about climate science, teachers can encourage students to use introductory-level statistics to analyze data for themselves on this important issue in public…

Teaching professionalism in science courses: anatomy to zoology.

PubMed

Macpherson, Cheryl C

2012-02-01

Medical professionalism is reflected in attitudes, behaviors, character, and standards of practice. It is embodied by physicians who fulfill their duties to patients and uphold societies' trust in medicine. Professionalism requires familiarity with the ethical codes and standards established by international, governmental, institutional, or professional organizations. It also requires becoming aware of and responsive to societal controversies. Scientific uncertainty may be used to teach aspects of professionalism in science courses. Uncertainty about the science behind, and the health impacts of, climate change is one example explored herein that may be used to teach both professionalism and science. Many medical curricula provide students with information about professionalism and create opportunities for students to reflect upon and strengthen their individually evolving levels of professionalism. Faculties in basic sciences are rarely called upon to teach professionalism or deepen medical students understanding of professional standards, competencies, and ethical codes. However they have the knowledge and experience to develop goals, learning objectives, and topics relevant to professionalism within their own disciplines and medical curricula. Their dedication to, and passion for, science will support basic science faculties in designing innovative and effective approaches to teaching professionalism. This paper explores topics and formats that scientists may find useful in teaching professional attitudes, skills, and competencies in their medical curriculum. It highlights goals and learning objectives associated with teaching medical professionalism in the basic sciences. Copyright © 2011. Published by Elsevier B.V.

Girls on Ice: Using Immersion to Teach Fluency in Science

NASA Astrophysics Data System (ADS)

Pettit, E. C.; Mortenson, C.; Stiles, K.; Coryell-Martin, M.; Long, L.

2010-12-01

Young women choose not to pursue science careers for several reasons; two important ones are that they more often lack the confidence in their own ability to succeed or they perceive many science jobs as isolated (working alone in a lab) or lacking in altruistic values of helping other people or communities. We developed an immersion-science program, Girls on Ice, to provide young women with strong, female role models; with an opportunity to see what a career in the Earth sciences is like; with one-on-one interactions with scientists; with facilitated discussions on the value of Earth science in societal issues such as climate change; and with challenges that will build their self-confidence in multiple ways. Girls on Ice is field-based program for teenage young women with the theme of Glaciers, Climate, and the Alpine Landscape. The concepts we cover range from glacier dynamics to alpine plant ecology to mountain weather. The educational goals are 1. to increase young women's self-efficacy and interest in pursuing science as a career, 2. to create life-long advocates for the scientific process and its role in public policy 3. to teach critical thinking skills which will be important for all of their future pursuits 4. to enhance their leadership self-confidence so that they have a higher likelihood of becoming community leaders in the future. The educational philosophy of Girls on Ice consists of three core values: that teaching the whole process of science gives students ownership of the science; that teaching to the whole student puts the science in context; and that diversity inspires new ideas, new approaches, and better science in the end. We use a field-based immersion format -- the science equivalent of language-immersion course - in order to achieve the goals listed above in a setting that emphasizes this educational philosophy. The immersion-style course creates a deep connection between science and daily life for these young women. Combined with climate

Using the CLEAN educational resource collection for building three-dimensional lessons to teach the climate system

NASA Astrophysics Data System (ADS)

Gold, A. U.; Sullivan, S. M.; Manning, C. L. B.; Ledley, T. S.; Youngman, E.; Taylor, J.; Niepold, F., III; Kirk, K.; Lockwood, J.; Bruckner, M. Z.; Fox, S.

2017-12-01

The impacts of climate change are a critical societal challenge of the 21st century. Educating students about the globally connected climate system is key in supporting the development of mitigation and adaptation strategies. Systems thinking is required for students to understand the complex, dynamic climate systems and the role that humans play within them. The interdisciplinary nature of climate science challenges educators, who often don't have formal training in climate science, to identify resources that are scientifically accurate before weaving them together into units that teach about the climate system. The Climate Literacy and Energy Awareness Network (CLEAN) supports this work by providing over 700 peer-reviewed, classroom-ready resources on climate and energy topics. The resource collection itself provide only limited instructional guidance, so educators need to weave the resources together to build multi-dimensional lessons that develop systems thinking skills. The Next Generation Science Standards (NGSS) science standards encourage educators to teach science in a 3-dimensional approach that trains students in systems thinking. The CLEAN project strives to help educators design NGSS-style, three-dimensional lessons about the climate system. Two approaches are currently being modeled on the CLEAN web portal. The first is described in the CLEAN NGSS "Get Started Guide" which follows a step-by-step process starting with the Disciplinary Core Idea and then interweaves the Cross-Cutting Concepts (CCC) and the Science and Engineering Practices (SEP) based on the teaching strategy chosen for the lesson or unit topic. The second model uses a climate topic as a starting place and the SEP as the guide through a four-step lesson sequence called "Earth Systems Investigations". Both models use CLEAN reviewed lessons as the core activity but provide the necessary framework for classroom implementation. Sample lessons that were developed following these two

Climate Literacy from the Plains to the Peaks: Challenges in Teaching Climate in Colorado Classrooms

NASA Astrophysics Data System (ADS)

Hafich, K. A.; Martens, W.; Fletcher, H.; MacFerrin, B.; Morrison, D.; Stone, J.; Collins, M. C.; Chastain, M.; Hager, C.; Duncan, E.; Gay, C. J.; Kurz, J. D.; Manning, C. B.; Graves, B. J.; Bloomfield, L.

2015-12-01

Boulder, Colorado is a central hub of climate research and education resources, yet teachers less than two hours away struggle to find relevant climate curriculum and meaningful connections to climate scientists. Learn More About Climate (LMAC), an initiative of the CU-Boulder Office for Outreach and Engagement was created to provide access to the most up-to-date scientific research in a user-friendly way that raises awareness and inspires an informed dialogue about climate change among Coloradans. LMAC produces classroom ready videos highlighting CU climate scientists, offers classroom visits and Skype sessions with scientists, and serves as a hub for the most recent climate news. LMAC recently formed a Teacher Advisory Board made up of eleven K12 teachers from across Colorado spanning rural, suburban, and urban school districts. Given different locations, demographics, and grade levels, each teacher faces different challenges teaching climate. Here we present our work to identify the primary challenges that our teacher advisors have encountered while teaching climate science in their classrooms. Furthermore, we are working to co-create dynamic solutions with the teachers to address these problems using the LMAC platform.

Teaching Climate Change Science in Senior Secondary School: Issues, Barriers and Opportunities

ERIC Educational Resources Information Center

Bunten, Rod; Dawson, Vaille

2014-01-01

This paper argues that, despite its difficulties, climate change can (and perhaps needs to) be taught rigorously to students by enquiry rather than through transmission and that such a method will enable students to make judgments on other issues of scientific controversy. It examines the issues and barriers to the teaching of climate change,…

Using Models to Teach about Climate Change: A look at NGSS Expectations and Teacher Perceptions

NASA Astrophysics Data System (ADS)

Yarker, M. B.; Stanier, C. O.; Forbes, C.; Park, S.

2013-12-01

The Next Generation Science Standards have been updated from the previous version of the standards with some much needed emphasis on topics in climate and climate change. In particular, the standards have focused on K-12 students learning about science models, which is extremely important when discussing climate change. The NGSS suggest that students be able to 1) develop and use science models (not just use them to explain a concept) because this is how scientists actually use models during the scientific process; and 2) understand systems and system models across all science concepts and all age levels because it leads to further understanding about a more complex natural system (like climate change). To summarize, the NGSS expects that K-12 students should develop and use system models across disciplines and age groups in a way that is similar to how scientists use them in practice, which is to make predictions about unanswered questions. Research indicates that students who learn about science content using an approach that aligns more authentically with the way real science inquiry is done have a better understanding of the content, better understanding of the nature of science, improved critical thinking skills, and improved problem solving skills. Research also indicates that most teachers are aware of this method to teach science content, but sometimes have trouble implementing it into the classroom effectively for many reasons. If accepted, this presentation will share an approach to incorporate modeling into the classroom effectively as well as report the results from a study that qualitatively look at three teacher's perspectives on using models in the classroom while teaching units about climate change, in order to identify how/why teachers struggle to teach about models involved in content related to climate change. Preliminary results indicate that the teachers in this study view models as an effective way to explain a concept to their students, but

Climate Communication from a Science Perspective

NASA Astrophysics Data System (ADS)

Somerville, R. C.

2012-12-01

Today, the world faces crucial choices in deciding what to do about climate change. Wise policy can be usefully informed by sound science. Scientists who are both climate experts and skilled communicators can provide valuable input into this policy process. They can help the public, media and policymakers learn what science has discovered about climate change. Scientists as a group are widely admired throughout the world. They can often use their prestige as well as their technical knowledge to advantage in publicizing and illuminating the findings of climate science. However, most scientists are unaware of the main obstacles to effective communication, such as the distrust that arises when the scientist and the audience do not have a shared worldview and shared cultural values. Many climate scientists also fail to realize that the jargon they use in their work is a significant barrier to communication, and that their messages requires skilled translation into the everyday language that people understand. Scientists need to recognize that lecturing is almost always poor communication. Speaking in a television interview or a Congressional hearing is completely unlike teaching a class of graduate students. The people whom one is trying to reach are rarely hungry for pure scientific information. Instead, they want to know how climate change will affect them and what can be done about it. Communicating climate science resembles skiing or speaking a foreign language: it is a skill that can be learned, but beginners are well advised to take lessons from expert instructors. Becoming adept at climate communication requires study and practice. Effective professional training in climate communication is available for those scientists who have the time and the willingness to improve as communicators.

What Is Motivating Middle-School Science Teachers to Teach Climate Change?

ERIC Educational Resources Information Center

McNeal, Peggy; Petcovic, Heather; Reeves, Patricia

2017-01-01

Adoption of science content standards that include anthropogenic climate change has prompted widespread instruction in climate change for the first time. However, the controversial nature of the topic can be daunting and many teachers share misconceptions that lead to weak treatment of climate change in classrooms. Nevertheless, numerous teachers…

Science teaching in science education

NASA Astrophysics Data System (ADS)

Callahan, Brendan E.; Dopico, Eduardo

2016-06-01

Reading the interesting article Discerning selective traditions in science education by Per Sund , which is published in this issue of CSSE, allows us to open the discussion on procedures for teaching science today. Clearly there is overlap between the teaching of science and other areas of knowledge. However, we must constantly develop new methods to teach and differentiate between science education and teaching science in response to the changing needs of our students, and we must analyze what role teachers and teacher educators play in both. We must continually examine the methods and concepts involved in developing pedagogical content knowledge in science teachers. Otherwise, the possibility that these routines, based on subjective traditions, prevent emerging processes of educational innovation. Modern science is an enormous field of knowledge in its own right, which is made more expansive when examined within the context of its place in society. We propose the need to design educative interactions around situations that involve science and society. Science education must provide students with all four dimensions of the cognitive process: factual knowledge, conceptual knowledge, procedural knowledge, and metacognitive knowledge. We can observe in classrooms at all levels of education that students understand the concepts better when they have the opportunity to apply the scientific knowledge in a personally relevant way. When students find value in practical exercises and they are provided opportunities to reinterpret their experiences, greater learning gains are achieved. In this sense, a key aspect of educational innovation is the change in teaching methodology. We need new tools to respond to new problems. A shift in teacher education is needed to realize the rewards of situating science questions in a societal context and opening classroom doors to active methodologies in science education to promote meaningful learning through meaningful teaching.

How Climate Science got to be in the Next Generation Science Standards (Invited)

NASA Astrophysics Data System (ADS)

Wysession, M. E.

2013-12-01

Climate science plays a prominent role in the new national K-12 Next Generation Science Standards (NGSS). This represents the culmination of a significant amount of effort by many different organizations that have worked hard to educate the public on one of the most interesting, complex, complicated, and societally important aspects of geoscience. While there are significant challenges to the full implementation of the NGSS, especially those aspects that relate to climate change, the fact that so many states are currently adopting the NGSS represents a significant milestone in geoscience education. When grade 6-12 textbooks were written ten years ago, such as Pearson's high school Physical Science: Concepts in Action (Wysession et al., 2004), very little mention of climate change was incorporated because it did not appear in state standards. Now, climate and climate change are an integral part of the middle school and high school NGSS standards, and textbook companies are fully incorporating this content into their programs. There are many factors that have helped the shift toward teaching about climate, such as the IPCC report, Al Gore's 'An Inconvenient Truth,' and the many reports on climate change published by the National Research Council (NRC). However, four major community-driven literacy documents (The Essential Principles of Ocean Science, Essential Principles and Fundamental Concepts for Atmospheric Science Literacy, The Earth Science Literacy Principles, and The Essential Principles of Climate Science) were essential in that they directly informed the construction of the Earth and Space Science (ESS) content of the NRC's 'Framework for K-12 Science Education' by the ESS Design Team. The actual performance expectations of the NGSS were then informed directly by the disciplinary core ideas of the NRC Framework, which were motivated by the community-driven literacy documents and the significant credentials these bore. The work in getting climate science

How Climate Science got to be in the Next Generation Science Standards (Invited)

NASA Astrophysics Data System (ADS)

Westnedge, K. L.; Dallimore, A.; Salish Sea Expedition Team

2011-12-01

Climate science plays a prominent role in the new national K-12 Next Generation Science Standards (NGSS). This represents the culmination of a significant amount of effort by many different organizations that have worked hard to educate the public on one of the most interesting, complex, complicated, and societally important aspects of geoscience. While there are significant challenges to the full implementation of the NGSS, especially those aspects that relate to climate change, the fact that so many states are currently adopting the NGSS represents a significant milestone in geoscience education. When grade 6-12 textbooks were written ten years ago, such as Pearson's high school Physical Science: Concepts in Action (Wysession et al., 2004), very little mention of climate change was incorporated because it did not appear in state standards. Now, climate and climate change are an integral part of the middle school and high school NGSS standards, and textbook companies are fully incorporating this content into their programs. There are many factors that have helped the shift toward teaching about climate, such as the IPCC report, Al Gore's 'An Inconvenient Truth,' and the many reports on climate change published by the National Research Council (NRC). However, four major community-driven literacy documents (The Essential Principles of Ocean Science, Essential Principles and Fundamental Concepts for Atmospheric Science Literacy, The Earth Science Literacy Principles, and The Essential Principles of Climate Science) were essential in that they directly informed the construction of the Earth and Space Science (ESS) content of the NRC's 'Framework for K-12 Science Education' by the ESS Design Team. The actual performance expectations of the NGSS were then informed directly by the disciplinary core ideas of the NRC Framework, which were motivated by the community-driven literacy documents and the significant credentials these bore. The work in getting climate science

Science Teaching in Science Education

ERIC Educational Resources Information Center

Callahan, Brendan E.; Dopico, Eduardo

2016-01-01

Reading the interesting article "Discerning selective traditions in science education" by Per Sund, which is published in this issue of "CSSE," allows us to open the discussion on procedures for teaching science today. Clearly there is overlap between the teaching of science and other areas of knowledge. However, we must…

Inspiring Climate Education Excellence(ICEE): Developing Elearning professional development modules - secondary science teachers

NASA Astrophysics Data System (ADS)

Kellagher, E.; Buhr, S. M.; Lynds, S. E.; McCaffrey, M. S.; Cires Education Outreach

2011-12-01

Inspiring Climate Education Excellence (ICEE) is a NASA-funded project to develop content knowledge and knowledge of effective teaching strategies in climate education among secondary science teachers. ICEE resources are aligned with the Essential Principles of Climate Science. Building upon a needs assessment and face to face workshop, ICEE resources include iTunesU videos, an ICEE 101 resource site with videos and peer-reviewed learning activities, and a moderated online forum. Self-directed modules and an online course are being developed around concepts and topics in which teachers express the most interest and need for instruction. ICEE resources include attention to effective teaching strategies, such as awareness of student misconceptions, strategies for forestalling controversy and advice from master teachers on implementation and curriculum development. The resources are being developed in partnership with GLOBE, and the National Science Digital Library (NSDL) and are informed by the work of the Climate Literacy and Energy Awareness Network (CLEAN) project. ICEE will help to meet the professional development needs of teachers, including those participating in the GLOBE Student Climate Research Campaign.

Climate Science - getting the world to understand, and to care

NASA Astrophysics Data System (ADS)

Jasmin, T.; Ackerman, S. A.; Whittaker, T. M.

2012-12-01

Effectively teaching and conveying climate science has become one of Earth Science's greatest challenges. Existing barriers are many and varied, from political, ideological, and religious, to purely economic. Additionally, studies show the general public at present has a surprising number of basic misconceptions regarding the Earth system, and Earth-Sun relationships. Addressing these misconceptions is the first hurdle to overcome for properly teaching climate science. This talk will discuss ways to address the various barriers. Strategies are being employed to arm teachers with new tools leveraging the move to online, interactive learning. Content can be tailored particular audiences. For any individual, learning will be most effective if there is an understood significance, the information is presented clearly and at an appropriate education level, and when possible some personal relevance can be inferred. People need a reason to care. Examples and approaches for several common education scenarios will be given. A simple "Climate Change 101" outline will be given, a blueprint that could be used to educate most of the general public. Freely available online resources to address Earth System misconceptions will be referenced. Finally, a case will be made that a dramatic improvement in climate literacy worldwide may be the only viable means to successfully tackling global warming.

3-D Teaching of Climate Change: An innovative professional learning model for K-12 teachers

NASA Astrophysics Data System (ADS)

Stapleton, M.; Wolfson, J.; Sezen-Barrie, A.

2017-12-01

In spite of the presumed controversy over the evidence for climate change, the recently released Next Generation Science Standards (NGSS) for K-12 include a focus on climate literacy and explicitly use the term `climate change.' In addition to the increased focus on climate change, the NGSS are also built upon a new three dimensional framework for teaching and learning science. Three dimensional learning has students engaging in scientific and engineering practices (Dimension 1), while using crosscutting concepts (Dimension 2) to explore and explain natural phenomena using disciplinary core ideas (Dimension 3). The adoption of these new standards in many states across the nation has created a critical need for on-going professional learning as in-service science educators begin to implement both climate change instruction and three dimensional teaching and learning in their classrooms. In response to this need, we developed an innovative professional learning model for preparing teachers to effectively integrate climate change into their new curriculum and engage students in three dimensional learning. Our professional learning model utilized ideas that have emerged from recent science education research and include: a) formative assessment probes for three dimensional learning that monitor students' progress; b) collaboration with scientists with expertise in climate science to understand the domain specific ways of doing science; and c) development of a community of practice for in-service teachers to provide feedback to each other on their implementation. In this poster presentation, we will provide details on the development of this professional learning model and discuss the affordances and challenges of implementing this type of professional learning experience.

Exploring Climate Science with WV Educators: A Regional Model for Teacher Professional Development

NASA Astrophysics Data System (ADS)

Ruberg, L. F.; Calinger, M.

2014-12-01

The National Research Council Framework for K-12 Science Literacy reports that children reared in rural agricultural communities, who experience regular interactions with plants and animals, develop more sophisticated understanding of ecology and biological systems than do urban and suburban children of the same age. West Virginia (WV) is a rural state. The majority of its residents live in communities of fewer than 2,500 people. Based on the features of the population being served and their unique strengths, this presentation focuses on a regional model for teacher professional development that addresses agricultural and energy vulnerabilities and adaptations to climate change in WV. The professional development model outlined shows how to guide teachers to use a problem-based learning approach to introduce climate data and analysis techniques within a scenario context that is locally meaningful. This strategy engages student interest by focusing on regional and community concerns. Climate science standards are emphasized in the Next Generation Science Standards, but WV has not provided its teachers with appropriate instructional resources to meet those standards. The authors addressed this need by offering a series of climate science education workshops followed by online webinars offered to WV science educators free of charge with funding by the West Virginia Space Grant Consortium. The authors report on findings from this series of professional development workshops conducted in partnership with the West Virginia Science Teachers Association. The goal was to enhance grades 5-12 teaching and learning about climate change through problem-based learning. Prior to offering the climate workshops, all WV science educators were asked to complete a short questionnaire. As Figure 1 shows, over 40% of the teacher respondents reported being confident in teaching climate science content. For comparison post workshops surveys measure teacher confidence in climate science

Climate Science Service Learning: Learning In Deed

NASA Astrophysics Data System (ADS)

Glass, D. S.

2012-12-01

Many schools require community service yet students work at a food bank or stream clean-up without understanding causes or solutions for the issues they encounter. Since students learn best when they make connections between scientific concepts and real-world issues that interest them, integrated science service learning is an effective and engaging way to teach. My fifth grade students at National Presbyterian School in Washington, DC learned about climate change through a service learning project to help the environment on campus. The curriculum was aligned with science and climate literacy frameworks, "Benchmarks for Science Literacy," from the American Academy for the Advancement of Science (AAAS) and "The Essential Principles of Climate Sciences," from the U.S. Global Change Research Program / U.S. Climate Change Science Program, and was supported through partnership with NOAA's Climate Stewards Education Program. The service learning project was implemented according to seven best practices of service learning: the students initiated the project, researched the issue, developed a plan, worked with the community, shared their results, reflected on the project, and celebrated their accomplishment. My class of 28 fifth-graders researched and experimented with several environmental variables affecting our campus. They brainstormed service projects they could do to help the environment and decided to focus on reducing idling in the school carpool lane. Students researched how automobile exhaust contributes to climate change, causes acid rain, and harms human health. Students designed a system to measure and eventually minimize the exhaust released by cars idling in the carpool line. They crafted a tally sheet to record the number and size of cars and their idling times. They measured temperature and CO2 data, although they did not find that the number of idling cars affected these variables. Students concluded that over an average week with pleasant weather, 35 of

Global Climates--Past, Present, and Future. Activities for Integrated Science Education.

ERIC Educational Resources Information Center

Henderson, Sandra, Ed.; And Others

Designed for integration into existing science curriculum for grades 8-10, this curriculum uses a current environmental issue, climate change, as a vehicle for teaching science education. Instructional goals include: (1) familiarize students with scientific methods; (2) help students understand the role of uncertainty; (3) encourage students to…

The Need to Introduce System Thinking in Teaching Climate Change

ERIC Educational Resources Information Center

Roychoudhury, Anita; Shepardson, Daniel P.; Hirsch, Andrew; Niyogi, Devdutta; Mehta, Jignesh; Top, Sara

2017-01-01

Research related to teaching climate change, system thinking, current reform in science education, and the research on reform-oriented assessment indicate that we need to explore student understanding in greater detail instead of only testing for an incremental gain in disciplinary knowledge. Using open-ended items we assessed details in student…

Preservice elementary teachers' personal science teaching efficacy and science teaching outcome expectancies: The influence of student teaching

NASA Astrophysics Data System (ADS)

Plourde, Lee Alton

This study was unique in garnering an early view at how the deterioration of science teacher education begins. This investigation examined the impact of the student teaching semester on preservice elementary teachers' personal efficacy beliefs and outcome expectancy beliefs in science teaching. Participants in the study included the student teachers of three separate cohort groups commencing and completing their student teaching semester at the same time. Qualitative data were gathered from interviews and observations from selected individuals of these cohort groups. Quantitative and qualitative research methods were employed in the study. Utilizing a pretest and posttest one group research design, quantitative data were obtained from the administration of a psychometric test, Science Teaching Efficacy Belief Instrument for preservice teachers (STEBI-B). The pretest was administered at the beginning of the student teaching semester, before the student teachers began their "soloing" teaching, and the posttest was administered at the completion of the student teaching semester and "soloing" period. Qualitative data were derived from interviews and observations which were audio recorded and transcribed. The results of this study revealed that the student teaching semester did not have a statistically significant impact on the subjects' sense of personal self-efficacy, but the influence was statistically significant in regards to the student teachers' beliefs about children's ability to learn science. Data gathered through interviews and observations suggested that beliefs appear to originate from one or more of the following: a lack of practical work, personal involvement, and hands-on manipulation in science related activities in elementary, secondary, and tertiary education; a dependence of science courses on textbooks and lectures; the dispassionate association with science teachers/instructors; a focus on formalized tests with no performance assessments; the

Revolutionizing Climate Science: Using Teachers as Communicators

NASA Astrophysics Data System (ADS)

Warburton, J.; Crowley, S.; Wood, J.

2012-12-01

PolarTREC (Teachers and Researchers Exploring and Collaborating) is a National Science Foundation (NSF) funded program in which K-12 teachers participate in hands-on field research experiences in the Polar Regions. Teachers are the dynamic conduits for communicating climate science. In the PolarTREC final report, researchers found that teachers were vital in refining the language of their science and have shaped the goals of the scientific project. Program data demonstrates that science in classrooms is better understood when teachers have a full-spectrum grasp of project intricacies from defining the project, to field data collection, encountering situations for creativity and critical thinking, as well as participating in data and project analysis. Teachers' translating the authentic scientific process is integral in communicating climate science to the broader public. Teachers playing a major role in polar science revolutionize the old paradigm of "in-school learning". Through daily online journaling and forums, social media communication, live webinars with public, and professional development events, these teachers are moving beyond classrooms to communicate with society. Through teachers, climate policy can be shaped for the future by having scientifically literate students as well as assessable science. New paradigms come as teachers attain proficient levels of scientific understanding paired with the expert abilities for communication with years of experience. PolarTREC teachers are a model for new interactions peer-to-peer learning and mentorship for young scientists. Our programmatic goal is to expand the opportunities for PolarTREC teachers to share their involvement in science with additional formal and informal educators. 'Teaching the teachers' will reach exponential audiences in media, policy, and classrooms. Modeling this program, we designed and conducted a teacher training on climate science in Denali National Park. Utilizing expert university

Implementation of an Online Climate Science Course at San Antonio College

NASA Astrophysics Data System (ADS)

Reyes, R.; Strybos, J.

2016-12-01

San Antonio College (SAC) plans to incorporate an online climate science class into the curriculum with a focus on local weather conditions and data. SAC is part of a network of five community colleges based around San Antonio, Texas, has over 20,000 students enrolled, and its student population reflects the diversity in ethnicity, age and gender of the San Antonio community. The college understands the importance of educating San Antonio residents on climate science and its complexities. San Antonio residents are familiar with weather changes and extreme conditions. The region has experienced an extreme drought, including water rationing in the city. Then, this year's El Niño intensified expected annual rainfalls and flash floods. The proposed climate science course will uniquely prepare students to understand weather data and the evidence of climate change impacting San Antonio at a local level. This paper will discuss the importance and challenges of introducing the new climate science course into the curriculum, and the desired class format that will increase the course's success. Two of the most significant challenges are informing students about the value of this class and identifying the best teaching format. Additionally, measuring and monitoring enrollment will be essential to determine the course performance and success. At the same time, Alamo Colleges is modifying the process of teaching online classes and is officially working to establish an online college. Around 23% of students enrolled in SAC offered courses are currently enrolled in online courses only, representing an opportunity to incorporate the climate science class as an online course. Since the proposed course will be using electronic textbooks and online applications to access hyperlocal weather data, the class is uniquely suited for online students.

Using "Making Sense of Climate Science Denial" MOOC videos in a college course

NASA Astrophysics Data System (ADS)

Schuenemann, K. C.; Cook, J.

2015-12-01

The Massive Open Online Course (MOOC) "Denial101x: Making Sense of Climate Science Denial" teaches students to make sense of the science and respond to climate change denial. The course is made up of a series of short, myth-debunking lecture videos that can be strategically used in college courses. The videos and the visuals within have proven a great resource for an introductory college level climate change course. Methods for using the videos in both online and in-classroom courses will be presented, as well as student reactions and learning from the videos. The videos introduce and explain a climate science topic, then paraphrase a common climate change myth, explain why the myth is wrong by identifying the characteristic of climate denial used, and concludes by reinforcing the correct science. By focusing on common myths, the MOOC has made an archive of videos that can be used by anyone in need of a 5-minute response to debunk a myth. By also highlighting five characteristics of climate denial: fake experts, logical fallacies, impossible expectations, cherry picking, and conspiracy theories (FLICC), the videos also teach the viewer the skills they need to critically examine myths they may encounter in the real world on a variety of topics. The videos also include a series of expert scientist interviews that can be used to drive home points, as well as put some faces to the science. These videos are freely available outside of the MOOC and can be found under the relevant "Most used climate myths" section on the skepticalscience.com webpage, as well as directly on YouTube. Discover ideas for using videos in future courses, regardless of discipline.

University-Level Teaching of Anthropogenic Global Climate Change (AGCC) via Student Inquiry

NASA Technical Reports Server (NTRS)

Bush, Drew; Sieber, Renee; Seiler, Gale; Chandler, Mark

2017-01-01

This paper reviews university-level efforts to improve understanding of anthropogenic global climate change (AGCC) through curricula that enable student scientific inquiry. We examined 152 refereed publications and proceedings from academic conferences and selected 26 cases of inquiry learning that overcome specific challenges to AGCC teaching. This review identifies both the strengths and weaknesses of each of these case studies. It is the first to go beyond examining the impact of specific inquiry instructional approaches to offer a synthesis of cases. We find that inquiry teaching can succeed by concretising scientific processes, providing access to global data and evidence, imparting critical and higher order thinking about AGCC science policy and contextualising learning with places and scientific facts. We recommend educational researchers and scientists collaborate to create and refine curricula that utilise geospatial technologies, climate models and communication technologies to bring students into contact with scientists, climate data and authentic AGCC research processes. Many available science education technologies and curricula also require further research to maximise trade-offs between implementation and training costs and their educational value.

Keeping the Hope: Seeing, Understanding, and Teaching Climate Change

NASA Astrophysics Data System (ADS)

Warburton, J.; Bartholow, S.; Larson, A.

2016-12-01

Climate Change: Seeing, Understanding, and Teaching in Denali is a four-day immersive teacher professional development course held in Denali National Park, Alaska. Now in it's fifth year, this field-based course has been developed in partnership with three organizations, Alaska Geographic, the National Park Service, and the Arctic Research Consortium of the United States. The course aims to develop teachers' skills for integrating climate change content into their classrooms. Throughout the course, participants gain skills in communicating science, increase their climate literacy, and learn how to facilitate classroom discussions that move us all towards making a positive impact on the future of climate change. This presentation aims to share tangible best practices for linking researchers and teachers through a field course that not only delivers content but also navigates the challenges of bringing climate change content to the classrooms. We will share data on how participants overwhelmingly value the deep commitment this course has to linking their field experience to the classroom attributing to the role of a teacher-leader; an expert science teacher with first-hand field research experience in the polar regions.

Teaching Science with Technology

NASA Astrophysics Data System (ADS)

Gornostaeva, Svetlana

2015-04-01

This is a short introduction about me, description of different teaching methods, which is used in my teaching practice of Geography, biology and GIS systems education. The main part is tell about practical lesson with lab Vernier. My name is Svetlana Gornostaeva. I am a geography, biology and GIS systems teacher in Tallinn Mustjõe Gymnasium (www.mjg.ee) and private school Garant (http://www.erakoolgarant.ee/). In my teaching practice I do all to show that science courses are very important, interesting, and do not difficult. I use differentiated instruction methods also consider individual needs. At lessons is used different active teaching methods such as individual work of various levels of difficulty, team works, creative tasks, interactive exercises, excursions, role-playing games, meeting with experts. On my lessons I use visual aids (maps, a collection of rocks and minerals, herbarium, posters, Vernier data logger). My favorite teaching methods are excursions, meeting with experts and practical lesson with lab Vernier. A small part of my job demonstrate my poster. In the next abstract I want to bring a one practical work with Vernier which I do with my students, when we teach a theme "Atmosphere and climate". OUTDOOR LEARNING. SUBJECT "ATMOSPHERE AND CLIMATE". WEATHER OBSERVATIONS WITH VERNIER DATA LOGGER. The aim: students teach to use Vernier data logger and measure climatic parameters such as: temperature, humidity, atmospheric pressure, solar radiation, ultraviolet light radiation, wind speed. In working process pupils also teach work together, observe natural processes, analyze. Children are working by small groups, 4-5 in each group. Every one should personally measure all parameters and put numbers into the table. After it group observe cloudiness, analyze table and give conclusion "Is at this moment dominates cyclone or anticyclone ?". Children really like this kind of job. Vernier data logger it is really fantastic tool. It is mobile lab. This

Nevada's Climate Change High School Science Fair Network

NASA Astrophysics Data System (ADS)

Buck, P.

2012-12-01

The purpose of this 3 year project funded by NSF (GEO 1035049) is to increase the climate change science content knowledge and teaching effectiveness of in-service high school science teachers and increase the numbers of quality of high school geoscience projects competing in Nevada's three regional Intel ISEF (International Science & Engineering Fair) affiliated science fairs. In year 1 of the project participants consisted of six female and three male high school teachers from across Nevada. Eight of the participants were white and one was Asian. Five participants taught in Clark County, two taught in Owyhee, one taught in Elko and one taught in Spring Creek. Over 20% of the projects were noted (by the teachers) as being submitted by underrepresented students; however, this information is not reliable as most students did not provide this data themselves. Pre-and post- content tests were given. Teachers improved from an average of eight missed on the pre-test to an average of only four items missed on the post-test. Participants were also asked to evaluate their own teaching efficacy. In general, participants had a strong science efficacy. The item on which there was the most discrepancy among participants was on #10, the one stating that "The low achievement of some students cannot generally be blamed on their teachers." Most teachers completed an end of year program evaluation. All but one of the participants felt that the pace of the workshop was comfortable. All participants who used faculty mentors in helping their students rated their faculty mentors very highly. All participants rated the program content very highly in terms of clarity, organization, relevance, helpfulness and usefulness. All participants gave the program a very high rating overall and stated they would likely use the information to mentor future students and in instruction in future classes. The science fairs are the culmination of the program. Teachers were required to have at least one

An Issues- and Concepts-Based Curriculum: Teaching about Climate Change

ERIC Educational Resources Information Center

Ross, Keith

2014-01-01

I argue that students want to see relevance in their studies. The National Curriculum in England is a list of concepts that we wish them to understand. However, the concepts need to be embedded into a meaningful context, such as climate change, which may become the overarching reason for teaching science. In this article I remember fondly…

Climate Change Science: The Literacy of Geography Teachers in the Western Cape Province, South Africa

ERIC Educational Resources Information Center

Anyanwu, Raymond; Le Grange, Lesley; Beets, Peter

2015-01-01

One of the universal responses to tackling global climate change is teaching climate change concepts at all levels of formal education. This response requires, among other things, teachers who are fully literate about climate change science, so that they can explain the concepts underlying the causes, impacts and solutions of climate change as…

The effects of a summer science camp teaching experience on preservice elementary teachers' science teaching efficacy, science content knowledge, and understanding of the nature of science

NASA Astrophysics Data System (ADS)

Logerwell, Mollianne G.

The purpose of this study was to investigate the impact of a summer science camp teaching experience on preservice elementary teachers' science teaching efficacy, science content knowledge, and understanding of the nature of science. Master's degree students enrolled in the elementary Fairfax Partnership Schools (FPS, n = 21) cohort served as the treatment group, while those enrolled in the Loudoun Partnership Schools (LPS, n = 15) and Professional Development Schools (PDS, n = 24) cohorts at George Mason University served as the control groups. The treatment group planned for and taught a two-week inquiry- and problem-based summer science camp as part of their science methods course, while the control groups did not. The Science Teaching Efficacy Belief Instrument (STEBI), a science content assessment, a personal data questionnaire, and a modified version of the Views of Nature of Science Questionnaire (VNOS-C) were administered to the participants at the beginning and end of their science methods course. Analyses revealed significant increases for the FPS group in general science teaching efficacy, personal science teaching efficacy, science teaching outcome expectancy, general science knowledge, biology content knowledge, chemistry content knowledge, and understanding of NOS; the LPS group in general science teaching efficacy, personal science teaching efficacy, chemistry content knowledge, and understanding of NOS; and, the PDS group in general science teaching efficacy, personal science teaching efficacy, and chemistry content knowledge. Additionally, the FPS group had significantly higher general science teaching efficacy than both control groups, personal science teaching efficacy than the PDS group, and understanding of NOS than the LPS group. Overall, the findings indicate that course length is not as important for developing preservice teachers' teaching efficacy and understanding of content as having connected, authentic field-based teaching experiences

Teaching Ethics in Science.

ERIC Educational Resources Information Center

Reiss, Michael

1999-01-01

Summarizes arguments for and against teaching ethics within science education, and clarifies what might be the several aims of teaching ethics in science. Discusses how ethics instruction might be incorporated into the science curriculum. (Contains 120 references.) (WRM)

Minority Preservice Teachers' Conceptions of Teaching Science: Sources of Science Teaching Strategies

ERIC Educational Resources Information Center

Subramaniam, Karthigeyan

2013-01-01

This study explores five minority preservice teachers' conceptions of teaching science and identifies the sources of their strategies for helping students learn science. Perspectives from the literature on conceptions of teaching science and on the role constructs used to describe and distinguish minority preservice teachers from their mainstream…

Teaching Children Science. Second Edition.

ERIC Educational Resources Information Center

Abruscato, Joseph

This book focuses on science teaching at the elementary school level. It includes chapters dealing with various science content areas and teaching processes including: (1) what is science; (2) why teach science; (3) process skills as a foundation for unit and lesson planning; (4) how to plan learning units, daily lessons, and assessment…

Confronting Barriers to Teaching Elementary Science: After-School Science Teaching Experiences for Preservice Teachers

ERIC Educational Resources Information Center

Cartwright, Tina; Smith, Suzanne; Hallar, Brittan

2014-01-01

This qualitative study examines the transition of eight elementary preservice teachers into student teaching after participating in a science methods course that included a significant amount of teaching after-school science to elementary grade students. These eight participants had a chance to practice teaching inquiry-based science and to reform…

Teaching about Climate Change and Energy with Online Materials and Workshops from On the Cutting Edge

NASA Astrophysics Data System (ADS)

Kirk, K. B.; Manduca, C. A.; Myers, J. D.; Loxsom, F.

2009-12-01

Global climate change and energy use are among the most relevant and pressing issues in today’s science curriculum, yet they are also complex topics to teach. The underlying science spans multiple disciplines and is quickly evolving. Moreover, a comprehensive treatment of climate change and energy use must also delve into perspectives not typically addressed in geosciences courses, such as public policy and economics. Thus, faculty attempting to address these timely issues face many challenges. To support faculty in teaching these subjects, the On the Cutting Edge faculty development program has created a series of websites and workshop opportunities to provide faculty with information and resources for teaching about climate and energy. A web-based collection of teaching materials was developed in conjunction with the On the Cutting Edge workshops “Teaching about Energy in Geoscience Courses: Current Research and Pedagogy.” The website is designed to provide faculty with examples, references and ideas for either incorporating energy topics into existing geoscience courses or for designing or refining a course about energy. The website contains a collection of over 30 classroom and lab activities contributed by faculty and covering such diverse topics as renewable energy, energy policy and energy conservation. Course descriptions and syllabi for energy courses address audiences ranging from introductory courses to advanced seminars. Other materials available on the website include a collection of visualizations and animations, a catalog of recommended books, presentations and related references from the teaching energy workshops, and ideas for novel approaches or new topics for teaching about energy in the geosciences. The Teaching Climate Change website hosts large collections of teaching materials spanning many different topics within climate change, climatology and meteorology. Classroom activities highlight diverse pedagogic approaches such as role

Mapping Climate Science Information Needs and Networks in the Northwest, USA through Evaluating the Northwest Climate Science Center Climate Science Digest

NASA Astrophysics Data System (ADS)

Gergel, D. R.; Watts, L. H.; Salathe, E. P.; Mankowski, J. D.

2017-12-01

Climate science, already a highly interdisciplinary field, is rapidly evolving, and natural resource managers are increasingly involved in policymaking and adaptation decisions to address climate change that need to be informed by state-of-the-art climate science. Consequently, there is a strong demand for unique organizations that engender collaboration and cooperation between government, non-profit, academic and for-profit sectors that are addressing issues relating to natural resources management and climate adaptation and resilience. These organizations are often referred to as boundary organizations. The Northwest Climate Science Center (NW CSC) and the North Pacific Landscape Conservation Cooperative (NP LCC) are two such boundary organizations operating in different contexts. Together, the NW CSC and the NP LCC fulfill the need for sites of co-production between researchers and managers working on climate-related issues, and a key component of this work is a monthly climate science newsletter that includes recent climate science journal articles, reports, and climate-related events. Our study evaluates the effectiveness of the climate science digest (CSD) through a three-pronged approach: a) in-depth interviews with natural resource managers who use the CSD, b) poll questions distributed to CSD subscribers, and c) quantitative analysis of CSD effectiveness using analytics from MailChimp distribution. We aim to a) map the reach of the CSD across the Northwest and at a national level; b) understand the efficacy of the CSD at communicating climate science to diverse audiences; c) evaluate the usefulness of CSD content for diverse constituencies of subscribers; d) glean transferrable knowledge for future evaluations of boundary management tools; and e) establish a protocol for designing climate science newsletters for other agencies disseminating climate science information. We will present results from all three steps of our evaluation process and describe

Linking Student Achievement and Teacher Science Content Knowledge about Climate Change: Ensuring the Nations 3 Million Teachers Understand the Science through an Electronic Professional Development System

NASA Astrophysics Data System (ADS)

Niepold, F.; Byers, A.

2009-12-01

The scientific complexities of global climate change, with wide-ranging economic and social significance, create an intellectual challenge that mandates greater public understanding of climate change research and the concurrent ability to make informed decisions. The critical need for an engaged, science literate public has been repeatedly emphasized by multi-disciplinary entities like the Intergovernmental Panel on Climate Change (IPCC), the National Academies (Rising Above the Gathering Storm report), and the interagency group responsible for the recently updated Climate Literacy: The Essential Principles of Climate Science. There is a clear need for an American public that is climate literate and for K-12 teachers confident in teaching relevant science content. A key goal in the creation of a climate literate society is to enhance teachers’ knowledge of global climate change through a national, scalable, and sustainable professional development system, using compelling climate science data and resources to stimulate inquiry-based student interest in science, technology, engineering, and mathematics (STEM). This session will explore innovative e-learning technologies to address the limitations of one-time, face-to-face workshops, thereby adding significant sustainability and scalability. The resources developed will help teachers sift through the vast volume of global climate change information and provide research-based, high-quality science content and pedagogical information to help teachers effectively teach their students about the complex issues surrounding global climate change. The Learning Center is NSTA's e-professional development portal to help the nations teachers and informal educators learn about the scientific complexities of global climate change through research-based techniques and is proven to significantly improve teacher science content knowledge.

Modeling Sources of Teaching Self-Efficacy for Science, Technology, Engineering, and Mathematics Graduate Teaching Assistants.

PubMed

DeChenne, Sue Ellen; Koziol, Natalie; Needham, Mark; Enochs, Larry

2015-01-01

Graduate teaching assistants (GTAs) in science, technology, engineering, and mathematics (STEM) have a large impact on undergraduate instruction but are often poorly prepared to teach. Teaching self-efficacy, an instructor's belief in his or her ability to teach specific student populations a specific subject, is an important predictor of teaching skill and student achievement. A model of sources of teaching self-efficacy is developed from the GTA literature. This model indicates that teaching experience, departmental teaching climate (including peer and supervisor relationships), and GTA professional development (PD) can act as sources of teaching self-efficacy. The model is pilot tested with 128 GTAs from nine different STEM departments at a midsized research university. Structural equation modeling reveals that K-12 teaching experience, hours and perceived quality of GTA PD, and perception of the departmental facilitating environment are significant factors that explain 32% of the variance in the teaching self-efficacy of STEM GTAs. This model highlights the important contributions of the departmental environment and GTA PD in the development of teaching self-efficacy for STEM GTAs. © 2015 S. E. DeChenne et al. CBE—Life Sciences Education © 2015 The American Society for Cell Biology. This article is distributed by The American Society for Cell Biology under license from the author(s). It is available to the public under an Attribution–Noncommercial–Share Alike 3.0 Unported Creative Commons License (http://creativecommons.org/licenses/by-nc-sa/3.0).

The Climate Literacy and Energy Awareness Network (clean) Pathway: Integrating Science and Solutions

NASA Astrophysics Data System (ADS)

Ledley, T. S.; McCaffrey, M. S.; Buhr, S.; Manduca, C. A.; Fox, S.; Niepold, F.; Gold, A. U.

2010-12-01

Changes in the climate system are underway, largely due to human impacts, and it is essential that citizens understand what these changes are, what is causing them, and the potential implications in order for them to make responsible decisions for themselves, their communities and society. The Climate Literacy Network (CLN) comprised of a broad spectrum of ~200 stakeholders, has virtual meetings weekly (since January 2008) to provide a forum to share information and leverage efforts to address the complex issues involved in making climate and energy literacy real in formal and informal educational contexts as well as for all citizens. The discussions of the CLN have led to 1) coordinated efforts to support the implementation of the Climate Literacy Essential Principles of Climate Science (CLEP, http://www.climatescience.gov/Library/Literacy/), 2) the establishment of the CLEAN Pathway collection (http://cleanet.org) of reviewed resources that directly support the CLEP, and 3) the development of a model for CLEAN-Regional Networks that facilitate increasing climate and energy literacy at the local level. In this presentation we will describe the ongoing activities of the CLN and provide an overview of the new and recently launched CLEAN Pathway collection. The CLEAN Pathway is a project to steward an on-line collection of digital teaching materials that directly address the CLEP as well as a set of energy awareness principles. All teaching materials are aligned with the NAAEE Guidelines for Excellence in Environmental Education, the AAAS Project 2061 Benchmarks for Science Literacy, and the National Science Education Standards. With a goal of vetting ~500 educational materials at the 6-16 grade levels, we have just completed our first round of identifying, reviewing and annotating ~100 excellent teaching activities. We will demonstrate the current capabilities of the CLEAN Pathway portal, describe plans for additional functionality, and provide a vision for others

Climate Change Science Teaching through Integration of Technology in Instruction and Research

NASA Astrophysics Data System (ADS)

Sriharan, S.; Ozbay, G.; Robinson, L.; Klimkowski, V.

2015-12-01

This presentation demonstrates the importance of collaborations between the institutions with common focus on offering the academic program on climate change science. Virginia State University (VSU) developed and established the course on climate change and adaptation, AGRI 350 for undergraduates, in cooperation with two HBCUs, Delaware State University (DSU) and Morgan State University (MSU). This program was developed to enhance the science curriculum with funding from the USDA NIFA. The hands-on research opportunities for students were supported by the NSF HBCU UP Supplement Grant at VSU. The technical guidance and lesson plans were available through the courtesy of the AMS and faculty/student team training at the NCAR. In the initial stages, the faculty members participated in faculty development workshops hosted by the AMS and NCAR. This contributed to trained faculty members developing the courses on Climate Change at VSU, DSU, and MSU. To create awareness of global climate change and exposure of students to international programs, seven students from VSU, MSU, and DSU participated in the Climate Change course (ENS 320) at the University of Sunshine Coast (USC), Australia. This international experience included faculty members in using SimCLIM for climate change data into decision-making with regard to potential changes to cropping systems and tree growth. The Climate Change program at VSU, DSU, and MSU is emerging into comprehensive academic program which includes use of case studies and exchange of students' reflections with their peers through discussion board and videoconferencing, hands-on research on water quality monitoring and mapping the study sites, and integration of geospatial technologies and i-Tree. In addition, the students' engagement in intensive research was conducted through hands-on experience with Scanning Electron Microscopy in the Marine Science Department, University of Hawaii at Hilo in summer 2015.

Exploring Science Teachers' Argumentation and Personal Epistemology About Global Climate Change

NASA Astrophysics Data System (ADS)

Liu, Shiyu; Roehrig, Gillian

2017-06-01

This case study investigated the nature of in-service science teachers' argumentation and personal epistemology about global climate change during a 3-year professional development program on climate change education. Qualitative analysis of data from interviews and written assessments revealed that while these teachers grounded their arguments on climate issues in evidence, the evidence was often insufficient to justify their causal claims. Compared with generating arguments for their own views, teachers had more difficulties in constructing evidence-based arguments for alternative perspectives. Moreover, while these teachers shared some similarities in their epistemology about climate science, they varied in their beliefs about specific aspects such as scientists' expertise and the credibility of scientific evidence. Such similarities and distinctions were shown to relate to how teachers used evidence to justify claims in their arguments. The findings also suggested a mismatch between teachers' personal epistemology about science in general and climate science, which was revealed through their argumentation. This work helps to further the ongoing discussions in environmental education about what knowledge and skills teachers need in order to teach climate issues and prepare students for future decision making. It constitutes first steps to facilitate reasoning and argumentation in climate change education and provides important implications for future design of professional development programs.

Modeling Sources of Teaching Self-Efficacy for Science, Technology, Engineering, and Mathematics Graduate Teaching Assistants

PubMed Central

DeChenne, Sue Ellen; Koziol, Natalie; Needham, Mark; Enochs, Larry

2015-01-01

Graduate teaching assistants (GTAs) in science, technology, engineering, and mathematics (STEM) have a large impact on undergraduate instruction but are often poorly prepared to teach. Teaching self-efficacy, an instructor’s belief in his or her ability to teach specific student populations a specific subject, is an important predictor of teaching skill and student achievement. A model of sources of teaching self-efficacy is developed from the GTA literature. This model indicates that teaching experience, departmental teaching climate (including peer and supervisor relationships), and GTA professional development (PD) can act as sources of teaching self-efficacy. The model is pilot tested with 128 GTAs from nine different STEM departments at a midsized research university. Structural equation modeling reveals that K–12 teaching experience, hours and perceived quality of GTA PD, and perception of the departmental facilitating environment are significant factors that explain 32% of the variance in the teaching self-efficacy of STEM GTAs. This model highlights the important contributions of the departmental environment and GTA PD in the development of teaching self-efficacy for STEM GTAs. PMID:26250562

Teachers' perceptions on primary science teaching

NASA Astrophysics Data System (ADS)

Kijkuakul, Sirinapa

2018-01-01

This qualitative research aimed to review what primary teachers think about how to teach science in rural school contexts. Three primary schools in Thailand were purposively chosen for this study. Eleven primary science teachers of these schools were the research participants. Questionnaires, interviews, and observations were implemented to reveal the primary school teachers' educational backgrounds, science teaching context, and need for self-driven professional development. Content and discourse analysis indicated that the non-science educational background and the science teaching context implied a need for self-driven professional development. The non-science educational background teachers were generally unfamiliar with the current national science curriculum, and that they would not be comfortable when the researcher observed their science teaching practice. They also believed that experimentation was the only one strategy for teaching science, and that the priority for their teaching support was teaching media rather than their understanding of scientific concepts or teaching strategies. As implication of this research, subsequent developments on science teacher profession in rural context, therefore, need to promote teachers' understandings of nature of science and technological and pedagogical content knowledge. In addition, they should be challenged to practice on critically participatory action research for academic growth and professional learning community.

CLIMANDES climate science e-learning course

NASA Astrophysics Data System (ADS)

Hunziker, Stefan; Giesche, Alena; Jacques-Coper, Martín; Brönnimann, Stefan

2016-04-01

Over the past three years, members of the Oeschger Centre for Climate Change Research (OCCR) and the Climatology group at the Institute of Geography at the University of Bern, have developed a new climate science e-learning course as part of the CLIMANDES project. This project is a collaboration between Peruvian and Swiss government, research, and education institutions. The aim of this e-learning material is to strengthen education in climate sciences at the higher education and professional level. The course was recently published in 2015 by Geographica Bernensia, and is hosted online by the Peruvian Servicio Nacional de Meteorología e Hidrología (SENAMHI): http://surmx.com/chamilo/climandes/e-learning/. The course is furthermore available for offline use through USB sticks, and a number of these are currently being distributed to regional training centers around the world by the WMO (World Meteorological Organization). There are eight individual modules of the course that each offer approximately 2 hours of individual learning material, featuring several additional learning activities, such as the online game "The Great Climate Poker" (http://www.climatepoker.unibe.ch/). Overall, over 50 hours of learning material are provided by this course. The modules can be integrated into university lectures, used as single units in workshops, or be combined to serve as a full course. This e-learning course presents a broad spectrum of topics in climate science, including an introduction to climatology, atmospheric and ocean circulation, climate forcings, climate observations and data, working with data products, and climate models. This e-learning course offers a novel approach to teaching climate science to students around the world, particularly through three important features. Firstly, the course is unique in its diverse range of learning strategies, which include individual reading material, video lectures, interactive graphics, responsive quizzes, as well as group

Science Teaching: What Does It Mean?

ERIC Educational Resources Information Center

Tseitlin, Michael; Galili, Igal

2006-01-01

This study considers the relationship between science, science teaching and the philosophy of science perceiving these three cultural phenomena as a semantic triad. This approach presents science teaching as being a form of a scientific reflection. The relationship of science teaching to the philosophy of science is advocated to be essential,…

The effect of electronic networking on preservice elementary teachers' science teaching self-efficacy and attitude towards science teaching

NASA Astrophysics Data System (ADS)

Mathew, Nishi Mary

Preservice elementary teachers' science teaching efficacy and attitude towards science teaching are important determinants of whether and how they will teach science in their classrooms. Preservice teachers' understanding of science and science teaching experiences have an impact on their beliefs about their ability to teach science. This study had a quasi-experimental pretest-posttest control group design (N = 60). Preservice elementary teachers in this study were networked through the Internet (using e-mail, newsgroups, listserv, world wide web access and electronic mentoring) during their science methods class and student practicum. Electronic networking provides a social context in which to learn collaboratively, share and reflect upon science teaching experiences and practices, conduct tele-research effectively, and to meet the demands of student teaching through peer support. It was hoped that the activities over the electronic networks would provide them with positive and helpful science learning and teaching experiences. Self-efficacy was measured using a 23-item Likert scale instrument, the Science Teaching Efficacy Belief Instrument, Form-B (STEBI-B). Attitude towards science teaching was measured using the Revised Science Attitude Scale (RSAS). Analysis of covariance was used to analyze the data, with pretest scores as the covariate. Findings of this study revealed that prospective elementary teachers in the electronically networked group had better science teaching efficacy and personal science teaching efficacy as compared to the non-networked group of preservice elementary teachers. The science teaching outcome expectancy of prospective elementary teachers in the networked group was not greater than that of the prospective teachers in the non-networked group (at p < 0.05). Attitude towards science teaching was not significantly affected by networking. However, this is surmised to be related to the duration of the study. Information about the

Teaching Earth System Science Using Climate Educational Modules Based on NASA and NOAA Resources

NASA Astrophysics Data System (ADS)

Ramirez, P. C.; LaDochy, S.; Patzert, W. C.; Willis, J. K.

2011-12-01

The Earth System Science Education Alliance (ESSEA) recently developed a set of climate related educational modules to be used by K-12 teachers. These modules incorporate recent NASA and NOAA resources in Earth Science education. In the summer of 2011, these modules were tested by in-service teachers in courses held at several college campuses. At California State University, Los Angeles, we reviewed two climate modules: The Great Ocean Conveyer Belt and Abrupt Climate Change (http://essea.strategies.org/module.php?module_id=148) and Sulfur Dioxide: Its Role in Climate Change (http://essea.strategies.org/module.php?module_id=168). For each module, 4-6 teachers formed a cohort to complete assignments and unit assessments and to evaluate the effectiveness of the module for use in their classroom. Each module presented the teachers with a task that enabled them to research and better understand the science behind the climate related topic. For The Great Ocean Conveyer Belt, teachers are tasked with evaluating the impacts of the slowing or stopping of the thermohaline circulation on climate. In the same module teachers are charged with determining the possibilities of an abrupt climate shift during this century such as happened in the past. For the Sulfur Dioxide module teachers investigated the climate implications of the occurrence of several major volcanic eruptions within a short time period, as well as the feasibility of using sulfates to geoengineer climate change. In completing module assignments, teachers must list what they already know about the topic as well as formulate questions that still need to be addressed. Teachers then model the related interactions between spheres comprising the earth system (atmosphere-lithosphere, for example) to evaluate possible environmental impacts. Finally, teachers applied their research results to create lesson plans for their students. At a time when climate change and global warming are important topics in science

Case study of science teaching in an elementary school: Characteristics of an exemplary science teacher

NASA Astrophysics Data System (ADS)

Kao, Huey-Lien

Improving the quality of science teaching is one of the greatest concerns in recent science education reform efforts. Many science educators suggest that case studies of exemplary science teachers may provide guidance for these reform efforts. For this reason, the characteristics of exemplary science teaching practices have been identified in recent years. However, the literature lacks research exploring exemplary teacher beliefs about the nature of science and science pedagogy, the relationships between their beliefs and practices, or how outstanding teachers overcome difficulties in order to facilitate their students' science learning. In this study, Sam-Yu, an identified exemplary science teacher who teaches in an elementary school in Pintung, Taiwan, was the subject. An interpretative research design (Erickson, 1986) based on principles of naturalistic inquiry (Lincoln & Guba, 1985) was used. Both qualitative and quantitative methods were employed in this case study. The qualitative method involved conducting interviews with the teacher and students, observing classroom activities and analyzing the structure of the learning materials. The quantitative methods involved using the Learning Climate Inventory (LCI) (Lin, 1997) instrument to assess the learning environment of the exemplary science classroom. This study found that Sam-Yu had a blend of views on the nature of science and a varied knowledge about science pedagogy. Personal preferences, past experiences, and the national science curriculum all played important roles in the development and refinement of Sam-Yu's beliefs about science and pedagogy. Regarding his teaching practices, Sam-Yu provided the best learning experiences, as evidenced in both classroom observations and the survey results, for his students by using a variety of strategies. In addition, his classroom behaviors were highly associated with his beliefs about science and pedagogy. However, due to school-based and socio-cultural constraints

Sample classroom activities based on climate science

NASA Astrophysics Data System (ADS)

Miler, T.

2009-09-01

We present several activities developed for the middle school education based on a climate science. The first activity was designed to teach about the ocean acidification. A simple experiment can prove that absorption of CO2 in water increases its acidity. A liquid pH indicator is suitable for the demonstration in a classroom. The second activity uses data containing coordinates of a hurricane position. Pupils draw a path of a hurricane eye in a tracking chart (map of the Atlantic ocean). They calculate an average speed of the hurricane, investigate its direction and intensity development. The third activity uses pictures of the Arctic ocean on September when ice extend is usually the lowest. Students measure the ice extend for several years using a square grid printed on a plastic foil. Then they plot a graph and discuss the results. All these activities can be used to improve the natural science education and increase the climate change literacy.

Lens on Climate Change (LOCC) - Engaging Diverse Secondary Students in Climate Science through Videography

NASA Astrophysics Data System (ADS)

Gold, Anne; Smith, Lesley; Leckey, Erin; Oonk, David; Woods, Melanie

2016-04-01

The impact of climate change is often discussed using examples from Polar Regions, such as decreasing polar bear populations, but significant changes are happening to local climates around the world. Climate change is often perceived as happening elsewhere, evoking a sense that others have to take action to mitigate climate change. Learning about climate change is very tangible for students when it addresses impacts they can observe close to their home. The Lens on Climate Change (LOCC) program engages students, ages 11to18 in producing short videos about climate change topics in Colorado, USA, specifically ones that are impacting students' lives and their local community. Participating schools are located in rural, suburban and urban Colorado many of which have diverse student populations often from socioeconomically disadvantaged backgrounds. Project staff recruits university graduate and undergraduate students to mentor the students in their research and video production. With the help of these mentors, student groups select and research climate topics, interview science experts and stakeholders, and produce short videos. The program aims to engage students in self-motivated research and learning about a climate topic. Furthermore, it serves as a way to spark students' interest in a career in science by matching them with college students for the program duration and bringing them to a university campus for a final screening event. For many of the students it is their first visit to a college campus. The LOCC project aims to connect secondary students, who otherwise would not have this opportunity, with college life and the scientific community. Evaluation results show that the process of video production is a powerful tool for the students to explore and learn about climate change topics. Students and teachers appreciate the unique approach to learning. The here presented approach of teaching science with videography in an active, self-directed style can easily

Earth Science Teaching Strategies Used in the International Polar Year

NASA Astrophysics Data System (ADS)

Sparrow, E. B.

2009-04-01

There are many effective methods for teaching earth science education that are being successfully used during the fourth International Polar Year (IPY). Relevance of IPY and the polar regions is better understood using a systems thinking approach used in earth science education. Changes in components of the earth system have a global effect; and changes in the polar regions will affect the rest of the world regions and vice versa. Teaching strategies successfully used for primary, secondary, undergraduate and graduate student earth science education and IPY education outreach include: 1) engaging students in earth science or environmental research relevant to their locale; 2) blending lectures with research expeditions or field studies, 3) connecting students with scientists in person and through audio and video conferencing; 4) combining science and arts in teaching, learning and communicating about earth science and the polar regions, capitalizing on the uniqueness of polar regions and its inhabitants, and its sensitivity to climate change; and 5) integrating different perspectives: western science, indigenous and community knowledge in the content and method of delivery. Use of these strategies are exemplified in IPY projects in the University of the Arctic IPY Higher Education Outreach Project cluster such as the GLOBE Seasons and Biomes project, the Ice Mysteries e-Polar Books: An Innovative Way of Combining Science and Literacy project, the Resilience and Adaptation Integrative Graduate Education and Research Traineeship project, and the Svalbard Research Experience for Undergraduates project.

A pragmatic conception of science: Implications for science teaching

NASA Astrophysics Data System (ADS)

Sessoms, Deidre Bates

In this dissertation, I examine various philosophical conceptions of the nature of science---its goals, methods and products---and link those views to how science is taught. While the review begins in the 1600s, the focus is primarily on logical positivism. The logical positivist view of science prevailed for much of the twentieth century and has greatly influenced how science is taught. The review section culminates with current conceptions of science from the fields of philosophy, sociology, feminist studies and radical studies of science. These various conceptions of the nature of science are linked to how science is currently taught, at the K--12 level and at the university. In particular, the logical positivist conception has influenced the teaching of science by emphasizing the products of science (factual knowledge and theories) over the processes of science (the social methods of knowledge production). As a result of viewing science as the logical positivists did, teachers primarily focus on science as unchanging factual knowledge, at the expense of examining the social and cultural aspects of scientific practices. I develop a pragmatic conception of the method of science as reflective thinking that we effectively use in our everyday lives. Linking that conception with the aims that John Dewey outlined for schools in a democratic society points the way towards certain goals and methods for teaching science. Therefore, I explore the type of science teaching that might result when viewing science as a pragmatic activity conducted in a democracy. Teaching of this sort would involve students in working together on shared problems that arise in the context of daily life. For science students at the university, this would include participating in and critiquing scientific research in active research laboratories. Implementing this view of science teaching might result in modifications in the practices and goals of science. Lastly, the experiences of a group of

Competencies in Science Teaching

ERIC Educational Resources Information Center

Mathelitsch, Leopold

2013-01-01

The role of competencies is discussed with respect to science teaching. In particular, competence models from Germany, Switzerland and Austria are presented and compared. A special topical program, "Competencies in Mathematics and Science Teaching", was started in Austria three years ago. Initial experiences with this program are…

Preservice Teachers' Perspectives on 'Appropriate' K-8 Climate Change and Environmental Science Topics

NASA Astrophysics Data System (ADS)

Ford, D. J.

2013-12-01

indicate that preservice teachers show interest in teaching children basic environmental science and conservation, but less interest in climate change science. Implications for instructors of both education and science courses will be discussed. We argue that it is important to consider not just the content taught to preservice teachers to prepare them for science teaching, but the ways in which we engage their beliefs about that content in relation to their beliefs about the capabilities of elementary and middle school learners.

Assessing the Credibility of Climate Science Information: A Roadmap for Educators

NASA Astrophysics Data System (ADS)

Mandia, S. A.

2017-12-01

Although there is an overwhelming scientific consensus that humans are driving modern day climate change, a significant portion of Americans are still not convinced. One reason for this gap in understanding results from a large body of misinformation that is easily accessible by students and educators. Here the author presents an effective teaching model to allow students to assess the credibility of organizations and their authors who publish climate science information aimed toward the general public.

A case study of teaching social responsibility to doctoral students in the climate sciences.

PubMed

Børsen, Tom; Antia, Avan N; Glessmer, Mirjam Sophia

2013-12-01

The need to make young scientists aware of their social responsibilities is widely acknowledged, although the question of how to actually do it has so far gained limited attention. A 2-day workshop entitled "Prepared for social responsibility?" attended by doctoral students from multiple disciplines in climate science, was targeted at the perceived needs of the participants and employed a format that took them through three stages of ethics education: sensitization, information and empowerment. The workshop aimed at preparing doctoral students to manage ethical dilemmas that emerge when climate science meets the public sphere (e.g., to identify and balance legitimate perspectives on particular types of geo-engineering), and is an example of how to include social responsibility in doctoral education. The paper describes the workshop from the three different perspectives of the authors: the course teacher, the head of the graduate school, and a graduate student. The elements that contributed to the success of the workshop, and thus make it an example to follow, are (1) the involvement of participating students, (2) the introduction of external expertise and role models in climate science, and (3) a workshop design that focused on ethical analyses of examples from the climate sciences.

Science-for-Teaching Discourse in Science Teachers' Professional Learning Communities

NASA Astrophysics Data System (ADS)

Lohwasser, Karin

Professional learning communities (PLCs) provide an increasingly common structure for teachers' professional development. The effectiveness of PLCs depends on the content and quality of the participants' discourse. This dissertation was conducted to add to an understanding of the science content needed to prepare to teach science, and the discourse characteristics that create learning opportunities in teachers' PLCs. To this end, this study examined how middle school science teachers in three PLCs addressed science-for-teaching, and to what effect. Insight into discourse about content knowledge for teaching in PLCs has implications for the analysis, interpretation, and support of teachers' professional discourse, their collaborative learning, and consequently their improvement of practice. This dissertation looked closely at the hybrid space between teachers' knowledge of students, of teaching, and of science, and how this space was explored in the discourse among teachers, and between teachers and science experts. At the center of the study were observations of three 2-day PLC cycles in which participants worked together to improve the way they taught their curriculum. Two of the PLC cycles were supported, in part, by a science expert who helped the teachers explore the science they needed for teaching. The third PLC worked without such support. The following overarching questions were explored in the three articles of this dissertation: (1) What kind of science knowledge did teachers discuss in preparation for teaching? (2) How did the teachers talk about content knowledge for science teaching, and to what effect for their teaching practice? (3) How did collaborating teachers' discursive accountabilities provide opportunities for furthering the teachers' content knowledge for science teaching? The teachers' discourse during the 2-day collaboration cycles was analyzed and interpreted based on a sociocultural framework that included concepts from the practice

Perspectives on learning, learning to teach and teaching elementary science

NASA Astrophysics Data System (ADS)

Avraamidou, Lucy

The framework that characterizes this work is that of elementary teachers' learning and development. Specifically, the ways in which prospective and beginning teachers' develop pedagogical content knowledge for teaching science in light of current recommendations for reform emphasizing teaching and learning science as inquiry are explored. Within this theme, the focus is on three core areas: (a) the use of technology tools (i.e., web-based portfolios) in support of learning to teach science at the elementary level; (b) beginning teachers' specialized knowledge for giving priority to evidence in science teaching; and (c) the applications of perspectives associated with elementary teachers' learning to teach science in Cyprus, where I was born and raised. The first manuscript describes a study aimed at exploring the influence of web-based portfolios and a specific task in support of learning to teach science within the context of a Professional Development School program. The task required prospective teachers to articulate their personal philosophies about teaching and learning science in the form of claims, evidence and justifications in a web-based forum. The findings of this qualitative case study revealed the participants' developing understandings about learning and teaching science, which included emphasizing a student-centered approach, connecting physical engagement of children with conceptual aspects of learning, becoming attentive to what teachers can do to support children's learning, and focusing on teaching science as inquiry. The way the task was organized and the fact that the web-based forum provided the ability to keep multiple versions of their philosophies gave prospective teachers the advantage of examining how their philosophies were changing over time, which supported a continuous engagement in metacognition, self-reflection and self-evaluation. The purpose of the study reported in the second manuscript was to examine the nature of a first

Controversy in Biology Classrooms—Citizen Science Approaches to Evolution and Applications to Climate Change Discussions

PubMed Central

Yoho, Rachel A.; Vanmali, Binaben H.

2016-01-01

The biological sciences encompass topics considered controversial by the American public, such as evolution and climate change. We believe that the development of climate change education in the biology classroom is better informed by an understanding of the history of the teaching of evolution. A common goal for science educators should be to engender a greater respect for and appreciation of science among students while teaching specific content knowledge. Citizen science has emerged as a viable yet underdeveloped method for engaging students of all ages in key scientific issues that impact society through authentic data-driven scientific research. Where successful, citizen science may open avenues of communication and engagement with the scientific process that would otherwise be more difficult to achieve. Citizen science projects demonstrate versatility in education and the ability to test hypotheses by collecting large amounts of often publishable data. We find a great possibility for science education research in the incorporation of citizen science projects in curriculum, especially with respect to “hot topics” of socioscientific debate based on our review of the findings of other authors. Journal of Microbiology & Biology Education PMID:27047604

Controversy in Biology Classrooms-Citizen Science Approaches to Evolution and Applications to Climate Change Discussions.

PubMed

Yoho, Rachel A; Vanmali, Binaben H

2016-03-01

The biological sciences encompass topics considered controversial by the American public, such as evolution and climate change. We believe that the development of climate change education in the biology classroom is better informed by an understanding of the history of the teaching of evolution. A common goal for science educators should be to engender a greater respect for and appreciation of science among students while teaching specific content knowledge. Citizen science has emerged as a viable yet underdeveloped method for engaging students of all ages in key scientific issues that impact society through authentic data-driven scientific research. Where successful, citizen science may open avenues of communication and engagement with the scientific process that would otherwise be more difficult to achieve. Citizen science projects demonstrate versatility in education and the ability to test hypotheses by collecting large amounts of often publishable data. We find a great possibility for science education research in the incorporation of citizen science projects in curriculum, especially with respect to "hot topics" of socioscientific debate based on our review of the findings of other authors. Journal of Microbiology & Biology Education.

The Teaching Processes of Prospective Science Teachers with Different Levels of Science-Teaching Self-Efficacy Belief

ERIC Educational Resources Information Center

Saka, Mehpare; Bayram, Hale; Kabapinar, Filiz

2016-01-01

The concept of self-efficacy, which is an important variable in the teaching process, and how it reflects on teaching have recently been the focus of attention. Therefore, this study deals with the relationship between the science-teaching self-efficacy beliefs of prospective science teachers and their teaching practices. It was conducted with…

Teaching Science as Science Is Practiced: Opportunities and Limits for Enhancing Preservice Elementary Teachers' Self-Efficacy for Science and Science Teaching

ERIC Educational Resources Information Center

Avery, Leanne M.; Meyer, Daniel Z.

2012-01-01

Science teaching in elementary schools, or the lack thereof, continues to be an area of concern and criticism. Preservice elementary teachers' lack of confidence in teaching science is a major part of this problem. In this mixed-methods study, we report the impacts of an inquiry-based science course on preservice elementary teachers' self-efficacy…

Teaching Ethical Issues in Science.

ERIC Educational Resources Information Center

Levinson, Ralph

This paper presents a study that investigates the teaching and learning aspects of controversial issues in science education. Teaching ethical issues is mandatory for science teachers in England; however, teachers may experience difficulties in exploring contemporary issues in science due to rapid and unpredictable changes. The study carries an…

Professional Development in Climate Science Education as a Model for Navigating the Next Generations Science Standards - A High School Science Teacher's Perspective

NASA Astrophysics Data System (ADS)

Manning, C.; Buhr, S. M.

2012-12-01

The Next Generation Science Standards attempt to move the American K12 education system into the 21st century by focusing on science and engineering practice, crosscutting concepts, and the core ideas of the different disciplines. Putting these standards into practice will challenge a deeply entrenched system and science educators will need significant financial support from state and local governments, professional development from colleges and universities, and the creation of collegial academic networks that will help solve the many problems that will arise. While all of this sounds overwhelming, there are proven strategies and mechanisms already in place. Educators who tackle challenging topics like global climate change are turning to scientists and other like-minded teachers. Many of these teachers have never taken a class in atmospheric science but are expected to know the basics of climate and understand the emerging science as well. Teachers need scientists to continue to reach out and provide rigorous and in-depth professional development opportunities that enable them to answer difficult student questions and deal with community misconceptions about climate science. Examples of such programs include Earthworks, ICEE (Inspiring Climate Education Excellence) and ESSEA (Earth System Science Education Alliance). Projects like CLEAN (Climate Literacy and Energy Awareness Network) provide excellent resources that teachers can integrate into their lessons. All of these benefit from the umbrella of documents like Climate Literacy: The Essential Principles of Climate Science. Support from the aforementioned networks has encouraged the development of effective approaches for teaching climate science. From the perspective of a Geoscience master teacher and instructional coach, this presentation will demonstrate how scientists, researchers, and science education professionals have created models for professional development that create long-term networks supporting

Successful Massive Open Online Climate Course on Climate Science and Psychology

NASA Astrophysics Data System (ADS)

Nuccitelli, D. A.; Cook, J.

2015-12-01

In 2015, the University of Queensland and edX launched a Massive Open Online Course (MOOC), 'Making Sense of Climate Science Denial.' The MOOC debunked approximately 50 common climate myths using elements of both physical science and psychology. Students learned how to recognise the social and psychological drivers of climate science denial, how to better understand climate change, how to identify the techniques and fallacies that climate myths employ to distort climate science, and how to effectively debunk climate misinformation. Contributors to the website Skeptical Science delivered the lectures, which were reinforced via interviews with climate science and psychology experts. Over 15,000 students from 167 countries enrolled in the course, and student feedback was overwhelmingly positive. This MOOC provides a model for effective climate science education.

Game Based Learning as a Means to Teach Climate Literacy in a High School Environment

NASA Astrophysics Data System (ADS)

Fung, M. K.; Tedesco, L.; Katz, M. E.

2013-12-01

As part of RPI's GK-12 graduate fellowship program (which involves graduate STEM fellows in K-12 education) a climate change board game activity was developed and implemented at inner city Troy High School in Troy, New York. The goal was to engage and teach two classes of the Earth Science General Repeat (GR) tenth grade students about climate change through a game-based leaning module. Students placed in the GR course had previously failed Earth Science, and had never passed a general science class in high school. In the past, these students have responded positively to hands-on activities. Therefore, an interactive board game activity was created to teach students about climate, explore how humans impact our environment, and address the future of climate change. The students are presented with a draft version of the game, created by the graduate fellow, and are asked to redesign the game for their peers in the other GR class. The students' version of the game is required to include certain aspects of the original game, for example, the climate change Trivia and Roadblock cards, but the design, addition of rules and overall layout are left to the students. The game-based learning technique allows the students to learn through a storyline, compete against each other, and challenge themselves to perfect their learning and understanding of climate change. The climate change board game activity also incorporates our cascade learning model, in which the graduate fellow designs the activity, works with a high school teacher, and implements the game with high school students. In addition, the activity emphasizes peer-to-peer learning, allowing each classroom to design the game for a different group of students. This allows the students to take leadership and gives them a sense of accomplishment with the completed board game. The nature of a board game also creates a dynamic competitive atmosphere, in which the students want to learn and understand the material to succeed

Raising Students' Perception of the Relevance of Science Teaching and Promoting Communication and Evaluation Capabilities Using Authentic and Controversial Socio-Scientific Issues in the Framework of Climate Change

ERIC Educational Resources Information Center

Feierabend, Timo; Eilks, Ingo

2010-01-01

This paper describes the development of different lesson plans dealing with authentic and controversial socio-scientific issues in the framework of climate change. These lesson plans orient themselves along the socio-critical, problem-oriented approach to science teaching. They deal with the use of bioethanol as an alternative fuel and with the…

Investigating Omani Science Teachers' Attitudes towards Teaching Science: The Role of Gender and Teaching Experiences

ERIC Educational Resources Information Center

Ambusaidi, Abdullah; Al-Farei, Khalid

2017-01-01

A 30-item questionnaire was designed to determine Omani science teachers' attitudes toward teaching science and whether or not these attitudes differ according to gender and teaching experiences of teachers. The questionnaire items were divided into 3 domains: classroom preparation, managing hands-on science, and development appropriateness. The…

Towards a Science of Science Teaching

ERIC Educational Resources Information Center

Yates, Carolyn

2009-01-01

This article is a contribution to the search for evidence-based models of learning to improve science education. The author believes that modern teachers should look to the sciences of cognitive psychology and neuroscience to build a science of science teaching. Understanding the relationships between learning and the brain's structure and…

Emotional climate of a pre-service science teacher education class in Bhutan

NASA Astrophysics Data System (ADS)

Rinchen, Sonam; Ritchie, Stephen M.; Bellocchi, Alberto

2016-09-01

This study explored pre-service secondary science teachers' perceptions of classroom emotional climate in the context of the Bhutanese macro-social policy of Gross National Happiness. Drawing upon sociological perspectives of human emotions and using Interaction Ritual Theory this study investigated how pre-service science teachers may be supported in their professional development. It was a multi-method study involving video and audio recordings of teaching episodes supported by interviews and the researcher's diary. Students also registered their perceptions of the emotional climate of their classroom at 3-minute intervals using audience response technology. In this way, emotional events were identified for video analysis. The findings of this study highlighted that the activities pre-service teachers engaged in matter to them. Positive emotional climate was identified in activities involving students' presentations using video clips and models, coteaching, and interactive whole class discussions. Decreases in emotional climate were identified during formal lectures and when unprepared presenters led presentations. Emotions such as frustration and disappointment characterized classes with negative emotional climate. The enabling conditions to sustain a positive emotional climate are identified. Implications for sustaining macro-social policy about Gross National Happiness are considered in light of the climate that develops in science teacher education classes.

Teaching Practical Watershed Science to non-Watershed Science Majors

NASA Astrophysics Data System (ADS)

Fassnacht, S. R.; Laituri, M.; Layden, P.; Coleman, R.

2008-12-01

The Warner College of Natural Resources (WCNR) at Colorado State University (CSU) has had a long tradition of integrating field measurements into the classroom, dating back to the first forestry summer camp held in 1917 at the CSU Pingree Park mountain campus. In the early 1960s, the Cooperative Watershed Management Unit coordinated efforts to understand and analyse the basic resources of the area, with an emphasis on the geology, hydrology, and climate. Much of this understand is now used as the Abiotic (Geology and Watershed) component of a five-credit, four-week course offered twice each summer at Pingree Park. With the exception of Geology students who have their own field course, this Natural Resources Ecology and Measurements course (NR 220) is required for all WCNR undergraduate students. These majors include Watershed Science, Forestry, Rangeland Ecology, Fisheries, Wildlife Biology, Conservation Biology, and Recreation and Tourism. Since most of these are students are much better trained in biological and/or social sciences rather than physical sciences, a challenge for the Watershed professor is to teaching practical Watershed Science to non-Watershed Science majors. This presentation describes how this challenge is met and how this course helps broaden the knowledge base of Natural Resources students.

Pedagogy of Science Teaching Tests: Formative assessments of science teaching orientations

NASA Astrophysics Data System (ADS)

Cobern, William W.; Schuster, David; Adams, Betty; Skjold, Brandy Ann; Zeynep Muğaloğlu, Ebru; Bentz, Amy; Sparks, Kelly

2014-09-01

A critical aspect of teacher education is gaining pedagogical content knowledge of how to teach science for conceptual understanding. Given the time limitations of college methods courses, it is difficult to touch on more than a fraction of the science topics potentially taught across grades K-8, particularly in the context of relevant pedagogies. This research and development work centers on constructing a formative assessment resource to help expose pre-service teachers to a greater number of science topics within teaching episodes using various modes of instruction. To this end, 100 problem-based, science pedagogy assessment items were developed via expert group discussions and pilot testing. Each item contains a classroom vignette followed by response choices carefully crafted to include four basic pedagogies (didactic direct, active direct, guided inquiry, and open inquiry). The brief but numerous items allow a substantial increase in the number of science topics that pre-service students may consider. The intention is that students and teachers will be able to share and discuss particular responses to individual items, or else record their responses to collections of items and thereby create a snapshot profile of their teaching orientations. Subsets of items were piloted with students in pre-service science methods courses, and the quantitative results of student responses were spread sufficiently to suggest that the items can be effective for their intended purpose.

The Graduate School of Climate Sciences, University of Bern

NASA Astrophysics Data System (ADS)

Martin, L.

2012-04-01

students in an ongoing research project and gives them the opportunity to collaborate with experienced scientists in a team. Alternatively, a short thesis (30 ECTS) may be combined with an internship (30 ECTS) at another university, in the private sector or in the administration. A bachelor degree in any field of science at university level (B.A. for specialisation in economics or history) or an equivalent degree is required for admission to the M.Sc. programme. The teaching language is English. The Ph.D. in Climate Sciences is research oriented and consists mainly of 3 to 4 years full time work in a project within one of the institutes involved in the Graduate School of Climate Sciences. The Ph.D. programme is research oriented and has a compulsory module of 12 ECTS credits containing workshops (professional skills), a summer school, an international conference, colloquia, seminars and optionally lectures. The compulsory module gives the Ph.D. students the opportunity to build up their own network in the local and international research community. The Ph.D. thesis is usually written in the form of research articles in international peer reviewed journals. A M.Sc. or an equivalent academic degree is conditional for admission to the Ph.D. programme.

Changes in Preservice Elementary Teachers' Personal Science Teaching Efficacy and Science Teaching Outcome Expectancies: The Influence of Context

ERIC Educational Resources Information Center

Hechter, Richard P.

2011-01-01

This study investigated contextual changes in perceptions of science teaching self-efficacy through pre-, post- and retrospective administrations of the Science Teaching Expectancy Belief Instrument (STEBI-B) among preservice elementary teachers when exposed to a science teaching methods course. Findings revealed that the number of postsecondary…

Climate Change Concepts and POGIL: Using climate change to teach general chemistry

NASA Astrophysics Data System (ADS)

King, D. B.; Lewis, J. E.; Anderson, K.; Latch, D.; Sutheimer, S.; Webster, G.; Middlecamp, C.; Moog, R.

2013-12-01

Climate change is a topic that can be used to engage students in a variety of courses and disciplines. Through an NSF-funded project, we have written a set of in-class POGIL (Process Oriented Guided Inquiry Learning) activities that use climate change topics to teach general chemistry concepts. POGIL is a pedagogical approach that uses group activities to teach content and process skills. In these group activities an initial model and a series of critical thinking questions are used to guide students through the introduction to or application of course content. Students complete the activities on their own, with the faculty member as a facilitator of learning, rather than a provider of information. Through assigned group roles and intentionally designed activity structure, process skills, such as teamwork, communication, and information processing, are developed during completion of the activity. While POGIL activities were initially developed for chemistry courses, this approach has now been used to create materials for use in other fields, such as biology, math, engineering and computer science. An additional component of this project is the incorporation of questions that relate to socio-scientific issues, e.g., the economic and social effects of climate change policies. The goal is for students to use evidence-based arguments in situations where opinion-based arguments are common. Key components (i.e., models and the corresponding critical thinking questions) of one activity will be presented. We will also report preliminary feedback based on initial classroom testing of several of the activities.

Methods of teaching the physics of climate change in undergraduate physics courses

NASA Astrophysics Data System (ADS)

Sadler, Michael

2015-04-01

Although anthropogenic climate change is generally accepted in the scientific community, there is considerable skepticism among the general population and, therefore, in undergraduate students of all majors. Students are often asked by their peers, family members, and others, whether they ``believe'' climate change is occurring and what should be done about it (if anything). I will present my experiences and recommendations for teaching the physics of climate change to both physics and non-science majors. For non-science majors, the basic approach is to try to develop an appreciation for the scientific method (particularly peer-reviewed research) in a course on energy and the environment. For physics majors, the pertinent material is normally covered in their undergraduate courses in modern physics and thermodynamics. Nevertheless, it helps to review the basics, e.g. introductory quantum mechanics (discrete energy levels of atomic systems), molecular spectroscopy, and blackbody radiation. I have done this in a separate elective topics course, titled ``Physics of Climate Change,'' to help the students see how their knowledge gives them insight into a topic that is very volatile (socially and politically).

Lessons learned from a rigorous peer-review process for building the Climate Literacy and Energy Awareness (CLEAN) collection of high-quality digital teaching materials

NASA Astrophysics Data System (ADS)

Gold, A. U.; Ledley, T. S.; McCaffrey, M. S.; Buhr, S. M.; Manduca, C. A.; Niepold, F.; Fox, S.; Howell, C. D.; Lynds, S. E.

2010-12-01

The topic of climate change permeates all aspects of our society: the news, household debates, scientific conferences, etc. To provide students with accurate information about climate science and energy awareness, educators require scientifically and pedagogically robust teaching materials. To address this need, the NSF-funded Climate Literacy & Energy Awareness Network (CLEAN) Pathway has assembled a new peer-reviewed digital collection as part of the National Science Digital Library (NSDL) featuring teaching materials centered on climate and energy science for grades 6 through 16. The scope and framework of the collection is defined by the Essential Principles of Climate Science (CCSP 2009) and a set of energy awareness principles developed in the project. The collection provides trustworthy teaching materials on these socially relevant topics and prepares students to become responsible decision-makers. While a peer-review process is desirable for curriculum developer as well as collection builder to ensure quality, its implementation is non-trivial. We have designed a rigorous and transparent peer-review process for the CLEAN collection, and our experiences provide general guidelines that can be used to judge the quality of digital teaching materials across disciplines. Our multi-stage review process ensures that only resources with teaching goals relevant to developing climate literacy and energy awareness are considered. Each relevant resource is reviewed by two individuals to assess the i) scientific accuracy, ii) pedagogic effectiveness, and iii) usability/technical quality. A science review by an expert ensures the scientific quality and accuracy. Resources that pass all review steps are forwarded to a review panel of educators and scientists who make a final decision regarding inclusion of the materials in the CLEAN collection. Results from the first panel review show that about 20% (~100) of the resources that were initially considered for inclusion

Useful and Usable Climate Science: Frameworks for Bridging the Social and Physical domains.

NASA Astrophysics Data System (ADS)

Buja, L.

2016-12-01

Society is transforming the Earth's system in unprecedented ways, often with significant variations across space and time. In turn, the impacts of climate change on the human system vary dramatically due to differences in cultural, socioeconomic, institutional, and physical processes at the local level. The Climate Science and Applications Program (CSAP) at the National Center for Atmospheric Research in Boulder Colorado addresses societal vulnerability, impacts and adaptation to climate change through the development of frameworks and methods for analyzing current and future vulnerability, and integrated analyses of climate impacts and adaptation at local, regional and global scales. CSAP relies heavily on GIS-based scientific data and knowledge systems to bridge social and physical science approaches in its five focus areas: Governance of inter-linked natural and managed resource systems. The role of urban areas in driving emissions of climate change Weather, climate and global human health, GIS-based science data & knowledge systems. Regional Climate Science and Services for Adaptation Advanced methodologies and frameworks for assessing current and future risks to environmental hazards through the integration of physical and social science models, research results, and remote sensing data are presented in the context of recent national and international projects on climate change and food/water security, urban carbon emissions, metropolitan extreme heat and global health. In addition, innovative CSAP international capacity building programs teaching interdisciplinary approaches for using geospatial technologies to integrate multi-scale spatial information of weather, climate change into important sectors such as disaster reduction, agriculture, tourism and society for decision-making are discussed.

Quality Teaching in Science: an Emergent Conceptual Framework

NASA Astrophysics Data System (ADS)

Jordens, J. Zoe; Zepke, Nick

2017-09-01

Achieving quality in higher education is a complex task involving the interrelationship of many factors. The influence of the teacher is well established and has led to some general principles of good teaching. However, less is known about the extent that specific disciplines influence quality teaching. The purposes of the paper are to investigate how quality teaching is perceived in the sciences and from these perceptions to develop for discussion a framework for teaching practice in the sciences. A New Zealand study explored the views of national teaching excellence award winners in science on quality teaching in undergraduate science. To capture all possible views from this expert panel, a dissensus-recognising Delphi method was used together with sensitising concepts based on complexity and wickedity. The emergent conceptual framework for quality teaching in undergraduate science highlighted areas of consensus and areas where there were a variety of views. About the purposes of science and its knowledge base, there was relative consensus, but there was more variable support for values underpinning science teaching. This highlighted the complex nature of quality teaching in science. The findings suggest that, in addition to general and discipline-specific influences, individual teacher values contribute to an understanding of quality in undergraduate science teaching.

The Teaching of Anthropogenic Climate Change and Earth Science via Technology-Enabled Inquiry Education

ERIC Educational Resources Information Center

Bush, Drew; Sieber, Renee; Seiler, Gale; Chandler, Mark

2016-01-01

A gap has existed between the tools and processes of scientists working on anthropogenic global climate change (AGCC) and the technologies and curricula available to educators teaching the subject through student inquiry. Designing realistic scientific inquiry into AGCC poses a challenge because research on it relies on complex computer models,…

The Machinery Of Climate Anti-Science, Its Efforts Against Education, Top To Bottom

NASA Astrophysics Data System (ADS)

Mashey, J. R.

2014-12-01

"There's always one every year" a fine local science teacher said after once again being hassled by a vocal parent for teaching appropriate climate science in school. How does that happen? The machinery of climate anti-science starts from the top with funders working through a maze of money paths, think tanks and front groups, employing spokespeople who can be portrayed as experts. While much of the money flows are still dark, some have been exposed over the last few years, and the effects finally filter down to the state and local levels of education. Among others, the Heartland Institute has a long history of trying to inject anti-science into K-12 and college education, having sent books, DVDs or brochures to teachers or school boards, as well as monthly newsletters to state legislators. Such are aimed at the top of the state or local organizations that affect education. For a vocal subset of the citizenry, a constant flow of misinformation from books, blogs, newsletters and some newspapers and magazines stirs action such as writing letters to editors, complaining to schools, calling on pseudo-experts and demanding equal time for pseudoscience. As the teacher said, it only takes one person to cause trouble at the local level. After a brief review of the overall machinery, this focuses on examples of anti-education tactics seen already, with some brief advice for climate scientists and educators who need to understand the machinery that supports such tactics. Some earlier history is included in http://www.desmogblog.com/2012/10/23/fakery-2-more-funny-finances-free-tax, but other attempts have surfaced in last few years, including state-wide efforts to reject Common Core Educational standard to avoid teaching climate science. Fortunately, school boards sometimes respond quite well, including one just recently in Pennsylvania.

How Often Do Early Childhood Teachers Teach Science Concepts? Determinants of the Frequency of Science Teaching in Kindergarten

ERIC Educational Resources Information Center

Saçkes, Mesut

2014-01-01

The purpose of the present study was to explore how often teachers of young children teach science concepts in kindergarten and examine the factors that influence the frequency of science teaching in early years. A theoretical model of the determinants of the frequency of science teaching in kindergarten was developed and tested using a…

Influencing Intended Teaching Practice: Exploring pre-service teachers' perceptions of science teaching resources

NASA Astrophysics Data System (ADS)

Cooper, Grant; Kenny, John; Fraser, Sharon

2012-08-01

Many researchers have identified and expressed concern over the state of science education internationally, but primary teachers face particular obstacles when teaching science due to their poor science background and low confidence with science. Research has suggested that exemplary resources, or units that work, may be an effective way to support primary teachers. This study explores the effect of one such resource on the intentions of pre-service primary teachers to teach science. The resource in question is Primary Connections, a series of learning resources produced by the Australian Academy of Science specifically designed for primary science. Evaluative studies of Primary Connections have indicated its efficacy with practising primary teachers but there is little evidence of its impact upon pre-service teachers. The purpose of this study was to investigate how effective these quality teaching resources were in influencing the intentions of primary pre-service teachers to teach science after they graduated. The theory of planned behaviour highlighted the linkage between the intentions of the pre-service teachers to teach science, and their awareness of and experiences with using Primary Connections during their education studies. This enabled key factors to be identified which influenced the intentions of the pre-service teachers to use Primary Connections to teach science after they graduate. The study also provided evidence of how quality science teaching resources can be effectively embedded in a teacher education programme as a means of encouraging and supporting pre-service teachers to teach science.

Teaching Science through Research.

ERIC Educational Resources Information Center

Hugerat, Muhamad; Zidani, Saleem; Kurtam, Naji

2003-01-01

Discusses the objectives of the science curriculum and the teacher's responsibility of passing through not only the required material, but also skills. Suggests that in order to improve teaching and learning skills, new strategies, such as teaching and learning through research must be utilized. Presents four examples of teaching and learning…

Teaching About Climate Change in Medical Education: An Opportunity

PubMed Central

Maxwell, Janie; Blashki, Grant

2016-01-01

Climate change threatens many of the gains in development and health over the last century. However, it could also be a catalyst for a necessary societal transformation to a sustainable and healthy future. Doctors have a crucial role in climate change mitigation and health system adaptation to prepare for emergent health threats and a carbon-constrained future. This paper argues that climate change should be integrated into medical education for three reasons: first, to prepare students for clinical practice in a climate-changing world; secondly, to promote public health and eco-health literacy; and finally, to deepen existing learning and strengthen graduate attributes. This paper builds on existing literature and the authors’ experience to outline potential learning objectives, teaching methods and assessment tasks. In the wake of recent progress at the United Nations climate change conference, COP-21, it is hoped that this paper will assist universities to integrate teaching about climate change into medical education. Significance for public health There is a strong case for teaching about climate change in medical education. Anthropogenic climate change is accepted by scientists, governments and health authorities internationally. Given the dire implications for human health, climate change is of fundamental relevance to future doctors. Integrating climate change into medical education offers an opportunity for future doctors to develop skills and insights essential for clinical practice and a public health role in a climate-changing world. This echoes a broader call for improved public health literacy among medical graduates. This paper provides medical schools with a rationale and an outline for teaching on climate change. PMID:27190980

Teaching About Climate Change in Medical Education: An Opportunity.

PubMed

Maxwell, Janie; Blashki, Grant

2016-04-26

Climate change threatens many of the gains in development and health over the last century. However, it could also be a catalyst for a necessary societal transformation to a sustainable and healthy future. Doctors have a crucial role in climate change mitigation and health system adaptation to prepare for emergent health threats and a carbon-constrained future. This paper argues that climate change should be integrated into medical education for three reasons: first, to prepare students for clinical practice in a climate-changing world; secondly, to promote public health and eco-health literacy; and finally, to deepen existing learning and strengthen graduate attributes. This paper builds on existing literature and the authors' experience to outline potential learning objectives, teaching methods and assessment tasks. In the wake of recent progress at the United Nations climate change conference, COP-21, it is hoped that this paper will assist universities to integrate teaching about climate change into medical education. Significance for public healthThere is a strong case for teaching about climate change in medical education. Anthropogenic climate change is accepted by scientists, governments and health authorities internationally. Given the dire implications for human health, climate change is of fundamental relevance to future doctors. Integrating climate change into medical education offers an opportunity for future doctors to develop skills and insights essential for clinical practice and a public health role in a climate-changing world. This echoes a broader call for improved public health literacy among medical graduates. This paper provides medical schools with a rationale and an outline for teaching on climate change.

Climate science in a postnormal context

NASA Astrophysics Data System (ADS)

Krauss, Werner; von Storch, Hans

2012-03-01

Postnormal Science: The Case of Climate Research; Hamburg, Germany, 4-6 May 2011 Climate research has left the narrow confines of pure science and has entered the public arena. At a workshop organized by Helmholtz Research Centre Geesthacht and the KlimaCampus, University of Hamburg, experts from the cultural, social, and natural sciences discussed the current state of climate science through the lens of "postnormal science" (see, e.g., S. O. Funtowicz and J. R. Ravetz, "Science for the postnormal age," Futures,25, 739-755, 1993). Science turns postnormal when facts are uncertain, stakes are high, values are disputed, and decisions are urgent. During the workshop, situations and practices in climate research were identified and discussed to provide a solid empirical basis for a more realistic definition of climate science.

Conceptualizing In-service Secondary School Science Teachers' Knowledge Base for Promoting Understanding about the Science of Global Climate Change

NASA Astrophysics Data System (ADS)

Bhattacharya, Devarati

Efforts to adapt and mitigate the effects of global climate change (GCC) have been ongoing for the past two decades and have become a major global concern. However, research and practice for promoting climate literacy and understanding about GCC have only recently become a national priority. The National Research Council (NRC), has recently emphasized upon the importance of developing learners' capacity of reasoning, their argumentation skills and understanding of GCC (Framework for K-12 Science Education, National Research Council, 2012). This framework focuses on fostering conceptual clarity about GCC to promote innovation, resilience, and readiness in students as a response towards the threat of a changing environment. Previous research about teacher understanding of GCC describes that in spite of the prevalent frameworks like the AAAS Science Literacy Atlas (AAAS, 2007) and the Essential Principles for Climate Literacy (United States Global Climate Research Program, 2009; Bardsley, 2007), most learners are challenged in understanding the science of GCC (Michail et al., 2007) and misinformed perceptions about basic climate science content and the role of human activities in changing climate remain persistent (Reibich and Gautier, 2006). Our teacher participants had a rather simplistic knowledge structure. While aware of climate change, teacher participants lacked in depth understanding of how change in climate can impact various ecosystems on the Earth. Furthermore, they felt overwhelmed with the extensive amount of information needed to comprehend the complexity in GCC. Hence, extensive efforts not only focused on assessing conceptual understanding of GCC but also for teaching complex science topics like GCC are essential. This dissertation explains concept mapping, and the photo elicitation method for assessing teachers' understanding of GCC and the use of metacognitive scaffolding in instruction of GCC for developing competence of learners in this complex

Collegiality and Better Science Teaching

ERIC Educational Resources Information Center

Weiser, Brenda

2012-01-01

For the past five years, teachers from four Houston-area school districts have joined together in a professional learning community (PLC) to improve their science teaching. Through the University of Houston-Clear Lake (UHCL) Regional Collaborative for Excellence in Science and Mathematics Teaching, the teachers strengthen content knowledge and…

Mixed Messages on Climate Science

NASA Astrophysics Data System (ADS)

Grifo, F.; Gutman, B. L.; Veysey, D.; El Gamal, A.

2011-12-01

While the private sector has a strong interest in climate science, and much at stake as the world comes to terms with the impacts of climate change, their legacy of climate denial has left the public confused. A few companies openly reject the basic science that ties emissions of greenhouse gases from human activities to warming temperatures and other consequences. Many companies play into the confusion by boasting of their green strategies while lobbying against climate bills. Still others joined pro-climate coalitions while donating heavily to politicians who openly reject the science of climate change. Many companies stand to see their business greatly affected by regulations to control greenhouse gas emissions or directly by changing weather patterns, rising sea levels, and varying water availability. Public statements, political activity, and corporate affiliations reveal inconsistent corporate postures. Congress, individuals, and the private sector can all play critical roles in holding corporate America to a higher standard bringing more clarity to science based climate policy discussions.

From learning science to teaching science: What transfers?

NASA Astrophysics Data System (ADS)

Harlow, Danielle Boyd

As educational researchers and teacher educators, we have the responsibility to help teachers gain the skills and knowledge necessary to provide meaningful learning activities for their students. For elementary school science, this means helping teachers create situations in which children can participate in the practices associated with scientific inquiry. Through the framework of transfer I investigated how a professional development course based on an inquiry-based physics curriculum influenced five elementary teachers teaching practices and identified the factors that led to or hindered this transfer. In this study, evidence of transfer consisted of episodes where the teachers used the ideas learned in the physics course to solve new problems such as transforming activities to be appropriate for their students and responding to unexpected students' ideas. The findings of this study highlight the many different ways that teachers use what they learn in content courses to teach science to elementary children. While some teachers transferred pedagogical practices along with the content, others transformed the content to be useful in already existing pedagogical frameworks, and still others show little or no evidence of transfer. What the teachers transferred depended upon their existing teaching context as well as their prior ideas about teaching science and physics content. Specifically, the findings of this study suggest that the teachers transferred only what they sought from the course. One implication of this study is that the sort of science training we provide teachers can affect far more than just the teachers' conceptual understanding of science and performance on written conceptual exams. Science courses have the potential to impact the sort of science education that K-5 children receive in elementary classrooms in terms of the topics taught but the way that science is represented. An additional implication is that teaching science to teachers in ways

Teaching science to science teachers: Lessons taught and lessons learned

NASA Astrophysics Data System (ADS)

Douglas, E. M.; Hashimoto-Martell, E. A.; Balicki, S.; Oglavie, D. R.

2009-12-01

The Boston Science Partnership has created a comprehensive set of graduate courses that immerse teachers in the science topics most relevant to their teaching practices. In these courses, teachers become students of science, developing their conceptual understandings through scientific inquiry. All courses are co-taught by a university faculty and teacher leaders from the Boston Public Schools. Each course provides contextual linkages between the science content and the standards-based curriculum of the Boston Public School district. One of the most relevant science topics to teachers and students of all disciplines is climate change. This served as the overarching theme for our course delivered during summer 2008 and 2009. This course focused on weather and the pivotal role that water and solar radiation play in the exchange of energy at the Earth's surface. Basic concepts such as the behavior of gases, energy flow, density changes, phase changes, heat capacities, and thermal convection were applied to examine short-term weather and water dynamics and longer-term impacts on global warming and climate change. The course was designed to embrace the 7E learning cycle and instructional model, as proposed by Eisenkraft in his landmark 2003 Science Teacher article. This inquiry-based instructional model builds upon prior conceptions and engages the learner in activities in which they begin to construct meaning of a concept prior to being given an explanation. Each day focused on an essential topic related to weather and climate change, and experiential learning was our main objective. There were many successes and challenges with our course. Twenty-five participants were enrolled, and all had different background knowledge and skill sets. Additionally, their level of teaching varied greatly, from K-12, so the level of depth with which to learn the content in order to bring it back to their classrooms varied a great deal as well. Therefore differentiating instruction for

Facilitating Elementary Science Teachers' Implementation of Inquiry-Based Science Teaching

ERIC Educational Resources Information Center

Qablan, Ahmad M.; DeBaz, Theodora

2015-01-01

Preservice science teachers generally feel that the implementation of inquiry-based science teaching is very difficult to manage. This research project aimed at facilitating the implementation of inquiry-based science teaching through the use of several classroom strategies. The evaluation of 15 classroom strategies from 80 preservice elementary…

A Study of Teacher Candidates' Experiences Investigating Global Climate Change Within an Elementary Science Methods Course

NASA Astrophysics Data System (ADS)

Hestness, Emily; Randy McGinnis, J.; Riedinger, Kelly; Marbach-Ad, Gili

2011-06-01

We investigated the inclusion of a curricular module on global climate change in an Elementary Science Methods course. Using complementary research methods, we analyzed findings from 63 teacher candidates' drawings, questionnaires, and journal entries collected throughout their participation in the module. We highlighted three focal cases to illustrate the diversity of participants' experiences. Findings suggest potential positive impacts on teacher candidates' content understanding related to global climate change, confidence to teach, and awareness of resources to support their future science instruction. Recommendations for science teacher education underscore the importance of providing opportunities for teacher candidates to increase their relevant content understanding, helping teacher candidates become familiar with appropriate curricular resources, and engaging in ongoing conversation and evaluation of developing views and understandings related to global climate change.

Provocative Opinion: Fads in Science Teaching

ERIC Educational Resources Information Center

Parry, R. W.

1975-01-01

Criticizes the post-Sputnik wave of multi-disciplinary science curricula aimed at teaching the students about social problems and how science can help solve these problems. Suggests that science teaching should concentrate more on the basics of a given discipline and should be taught be specialists rather than generalists. (MLH)

Teaching the Human Dimension of Science

ERIC Educational Resources Information Center

Farland-Smith, Donna; McComas, William

2009-01-01

Teachers have the important responsibility of providing students with accurate and engaging science content while also helping them establish authentic views of scientists. Though there are numerous curriculum materials to assist in the teaching of science content, the authors have found that methods and materials to teach science as a human…

UWHS Climate Science: Uniting University Scientists and High School Teachers in the Development and Implementation of a Dual-Credit STEM-Focused Curriculum

NASA Astrophysics Data System (ADS)

Bertram, M. A.; Thompson, L.; Ackerman, T. P.

2012-12-01

The University of Washington is adapting a popular UW Atmospheric Sciences course on Climate and Climate Change for the high school environment. In the process, a STEM-focused teaching and learning community has formed. With the support of NASA Global Climate Change Education 20 teachers have participated in an evolving professional development program that brings those actively engaged in research together with high school teachers passionate about bringing a formal climate science course into the high school. Over a period of several months participating teachers work through the UW course homework and delve deeply into specific subject areas. Then, during a week-long summer institute, scientists bring their particular expertise (e.g. radiation, modeling) to the high school teachers through lectures or labs. Together they identify existing lectures, textbook material and peer-reviewed resources and labs available through the internet that can be used to effectively teach the UW material to the high school students. Through this process the scientists learn how to develop teaching materials around their area of expertise, teachers engage deeply in the subject matter, and both the university and high school teachers are armed with the tools to effectively teach a STEM-focused introductory course in climate science. To date 12 new hands-on modules have been completed or are under development, exploring ice-cores, isotopes, historical temperature trends, energy balance, climate models, and more. Two modules have been tested in the classroom and are ready for peer-review through well-respected national resources such as CLEAN or the National Earth Science Teachers Association; three others are complete and will be implemented in a high school classroom this year, and the remainder under various stages of development. The UWHS ATMS 211 course was piloted in two APES (Advanced Placement Environmental Science classrooms) in Washington State in 2011/2012. The high school

Peer Assessment of Elementary Science Teaching Skills

ERIC Educational Resources Information Center

Kilic, Gulsen Bagci; Cakan, Mehtap

2007-01-01

In this study, peer assessment was applied in assessing elementary science teaching skills. Preservice teachers taught a science topic as a team to their peers in an elementary science methods course. The peers participating in the science lesson assessed teacher-groups' elementary science teaching skills on an assessment form provided by the…

Studies on attitude toward teaching science and anxiety about teaching science in preservice elementary teachers

NASA Astrophysics Data System (ADS)

Westerback, Mary E.

These studies examined attitude toward teaching science (ATTS) using an adaptation of the Bratt Attitude Test (M-BAT); anxiety about teaching science (ANX-TS), as measured by the State-Trait Anxiety Inventory (STAI A-State); and selected demographic variables in preservice elementary teachers for the 1977-1978 and 1978-1979 academic years and a follow-up of those students who completed their student teaching in May 1979. The M-BAT and STAI were administered in September at the beginning of Science 6 (earth science and biology course), in December on the next to last day of Science 6, in May on the next to the last day of Science 5 (physical science), and in May 1979 after student teaching. In the two academic years, both ATTS and ANX-TS became more positive during the sequence Science 6-5. Both changes in ATTS and ANX-TS continued to change in a positive direction after completion of Science 6-5, after student teaching. There were differences in the times that the greatest changes in ATTS and ANX-TS occurred. In both studies, the greatest change in ATTS took place between September and December, during Science 6. The greatest change in ANX-TS, however, took place during Science 5 between December and May in the 1977-1978 study. In the 1978-1979 study, the greatest changes in ANX-TS occurred in Science 6, between September and December. The delayed reduction of ANX-TS in the 1977-1978 study may be explained by differences in teaching patterns. In 1977-1978, two teachers taught only their academic specialty, biology or earth science, to students who switched teachers midsemester. In 1978-1979, the same two instructors taught both biology and earth science to the same students. Correlation coefficients for successive and corresponding administrations of both the M-BAT and STAI suggest these variables are related. Students with more positive ATTS tended to have reduced ANX-TS. Neither the number of high school or college science and math courses completed nor the level

Using Planetarium Programs to Teach Climate Change

NASA Astrophysics Data System (ADS)

Reiff, P. H.; Sumners, C.; Handron, K.

2007-12-01

By creating engaging and entertaining fulldome immersive planetarium shows, we are able to "sneak the science in", teaching about climate change on short, long, and extremely long time scales. In our show "Force 5", we talk about the shortest times: not really climate, but weather, including hurricanes, tornadoes, and space storms. Our show "Night of the Titanic" extends the time line to include changes in ocean currents, glaciers, and icebergs on decadal time periods, associated with global warming and changes in the sun. Our show "Dinosaur Prophecy" uses four dinosaur death sites to investigate the long-term changes or events that caused their demise. And finally, in "Lucy's Cradle: the Birth of Wonder" we investigate very long-term changes that spurred human development and migration. In this paper we discuss the techniques of creating planetarium shows and the "Discovery Dome" outreach network which has grown from six sites to 30 sites in 15 states and 7 countries. If space allows, we will demonstrate the shows in a portable dome in the poster session.

Preservice Science Teachers' Science Teaching Orientations and Beliefs about Science

ERIC Educational Resources Information Center

Kind, Vanessa

2016-01-01

This paper offers clarification of science teacher orientations as a potential component of pedagogical content knowledge. Science teaching orientations and beliefs about science held by 237 preservice science teachers were gathered via content-specific vignettes and questionnaire, respectively, prior to participation in a UK-based teacher…

Teaching the Intersection of Climate and Society

NASA Astrophysics Data System (ADS)

Thomson, C.; Ting, M.; Orlove, B. S.

2014-12-01

As the first program of its kind, the M.A. in Climate and Society at Columbia University educates students on how climate affects society and vice versa. The 12-month interdisciplinary Master's program is designed to allow students from a wide variety of backgrounds to gain knowledge in climate science and a deep understanding of social sciences and how they related to climate. There are currently more than 250 alumni applying their skills in fields including energy, economics, disaster mitigation, journalism and climate research in more than a dozen countries worldwide. The presentation will highlight three key components of the program that have contributed to its growth and helped alumni become brokers that can effectively put climate science in the hands of the public and policymakers for the benefit of society. Those components include working with other academic departments at Columbia to successfully integrate social science classes into the curriculum; the development of the course Applications in Climate and Society to help students make an overt link between climate and its impacts on society; and providing students with hands-on activities with practitioners in climate-related fields.

Using an Interdisciplinary Approach to Enhance Climate Literacy for K-12 Teachers

NASA Astrophysics Data System (ADS)

Hanselman, J. A.; Oches, E. A.; Sliko, J.; Wright, L.

2014-12-01

The Next Generation Science Standards (2014) will begin to change how K-12 teachers teach science. Using a scaffolding approach, the standards focus on a depth of knowledge across multiple content areas. This philosophy should encourage inquiry-based teaching methods, provided the teacher has both the knowledge and the confidence to teach the content. Although confidence to teach science is high among secondary science (biology, general science, chemistry) teachers, depth of knowledge may be lacking in certain areas, including climate science. To address this issue, a graduate course in climate science (Massachusetts Colleges Online Course of Distinction award winner) was developed to include inquiry-based instruction, connections to current research, and interdisciplinary approaches to teaching science. With the support of the InTeGrate program (SERC) at Carleton College, a module was developed to utilize cli-fi (climate science present in fictional literature) and related climate data. Graduate students gain an appreciation of scientific communication and an understanding of climate data and its connection to societal issues. In addition, the graduate students also gain the ability to connect interdisciplinary concepts for a deeper understanding of climate science and have the opportunity. By the end of the course, the graduate students use the content learned and the examples of pedagogical tools to develop their own activities in his or her classroom.

Teaching Science through Inquiry

ERIC Educational Resources Information Center

Wilcox, Jesse; Kruse, Jerrid W.; Clough, Michael P.

2015-01-01

Science education efforts have long emphasized inquiry, and inquiry and scientific practices are prominent in contemporary science education reform documents (NRC 1996; NGSS Lead States 2013). However, inquiry has not become commonplace in science teaching, in part because of misunderstandings regarding what it means and entails (Demir and Abell…

Middle school science teachers' teaching self-efficacy and students' science self-efficacy

NASA Astrophysics Data System (ADS)

Pisa, Danielle

Project 2061, initiated by the American Association for the Advancement of Science (AAAS), developed recommendations for what is essential in education to produce scientifically literate citizens. Furthermore, they suggest that teachers teach effectively. There is an abundance of literature that focuses on the effects of a teacher's science teaching self-efficacy and a student's science self-efficacy. However, there is no literature on the relationship between the two self-efficacies. This study investigated if there is a differential change in students' science self-efficacy over an academic term after instruction from a teacher with high science teaching self-efficacy. Quantitative analysis of STEBI scores for teachers showed that mean STEBI scores did not change over one academic term. A t test indicated that there was no statistically significant difference in mean SMTSL scores for students' science self-efficacy over the course of one academic term for a) the entire sample, b) each science class, and c) each grade level. In addition, ANOVA indicated that there was no statistically significant difference in mean gain factor of students rated as low, medium, and high on science self-efficacy as measured by the SMTSL, when students received instruction from a teacher with a high science teaching self-efficacy value as measured by the STEBI. Finally, there was no statistically significant association between the pre- and post-instructional rankings of SMTSL by grade level when students received instruction from a teacher with a high science teaching self-efficacy value as measured by the STEBI. This is the first study of its kind. Studies indicated that teaching strategies typically practiced by teachers with high science teaching were beneficial to physics self-efficacy (Fencl & Scheel, 2005). Although it was unsuccessful at determining whether or not a teacher with high science teaching self-efficacy has a differential affect on students' science self

My Science Is Better than Your Science: Conceptual Change as a Goal in Teaching Science Majors Interested in Teaching Careers about Education

ERIC Educational Resources Information Center

Utter, Brian C.; Paulson, Scott A.; Almarode, John T.; Daniel, David B.

2018-01-01

We argue, based on a multi-year collaboration to develop a pedagogy course for physics majors by experts in physics, education, and the science of learning, that the process of teaching science majors about education and the science of learning, and evidence-based teaching methods in particular, requires conceptual change analogous to that…

Professional development in college science teaching

NASA Astrophysics Data System (ADS)

Thomas, Aimee Kathryn

Graduate students earning a doctorate in the sciences historically focus their work on research and not professional development in college science teaching. However, for those who go on to a career in academia, a majority of their time will be dedicated to teaching. During the past few years, graduate teaching assistants (GTAs) have been prepared to teach by attending a daylong workshop that included logistical information, but left pedagogy largely unexplored. Since that time, a seminar has been added to provide an introduction to pedagogical theory and practices and to provide practice teaching in the biological sciences laboratory course. Yet, more pedagogical preparation is needed. This study was conducted to determine if there was a need for a teaching certificate program for doctoral students in the College of Science and Technology (CoST) at The University of Southern Mississippi. The GTA respondents studied set teaching goals that were consistent with faculty members across the country; however, this research went further by finding out how competent the GTAs perceived they were and how much support they perceived they needed with respect to teaching and professional development. The GTAs did not differ in their perceived level of competence based on experience level; however, the less experienced GTAs did perceive they needed more support than the experienced GTAs. To help GTAs develop a skill set that many CoST graduates currently lack, it is recommended that the University provide ample training and supervision. Establishing a certificate program can potentially impact the community in the following ways: (1) the training of GTAs contributes to the academic preparation of future academic professionals who will be teaching in various institutions; (2) GTA training provides professional development and awareness that teaching requires life long professional development; (3) ensuring competent academicians, not only in content but also in pedagogy; (4

Epistemological Beliefs and Practices of Science Faculty with Education Specialties: Combining Teaching Scholarship and Interdisciplinarity

NASA Astrophysics Data System (ADS)

Addy, Tracie Marcella

2011-12-01

departmental emphasis on teaching scholarship. These findings support the epistemological beliefs of this cohort of SFES as congruent with the recommendations given by the National Research Council on educational reform. Further research is needed to understand the teaching beliefs and practices of SFES compared their non-SFES colleagues, the departmental climates of SFES, the influence of the classroom practices of SFES on student learning and achievement in science, and SFES belief systems within particular STEM disciplines. SFES may play a crucial role at enacting reform-based teaching within undergraduate science courses across our nation, and address the needs of STEM education brought forward by national calls to action.

Science Teaching in Rhodesia

ERIC Educational Resources Information Center

Smith, A. L.

1975-01-01

Describes science teaching in Rhodesia as beset with limitations in the quality of students, in student motivation, in the number and quality of teachers, in the Rhodesian environment, and in the science syllabuses themselves. (Author/GS)

Pedagogy of Science Teaching Tests: Formative Assessments of Science Teaching Orientations

ERIC Educational Resources Information Center

Cobern, William W.; Schuster, David; Adams, Betty; Skjold, Brandy Ann; Mugaloglu, Ebru Zeynep; Bentz, Amy; Sparks, Kelly

2014-01-01

A critical aspect of teacher education is gaining pedagogical content knowledge of how to teach science for conceptual understanding. Given the time limitations of college methods courses, it is difficult to touch on more than a fraction of the science topics potentially taught across grades K-8, particularly in the context of relevant pedagogies.…

Teaching about Teaching Science: Aims, Strategies, and Backgrounds of Science Teacher Educators

ERIC Educational Resources Information Center

Berry, Amanda; Van Driel, Jan H.

2013-01-01

Despite pressing concerns about the need to prepare high-quality teachers and the central role of teacher educators (TEs) in this process, little is known about how TEs teach about teaching specific subject matter, and how they develop their expertise. This empirical study focuses on the specific expertise that science TEs bring into teacher…

Teaching With and About Nature of Science, and Science Teacher Knowledge Domains

NASA Astrophysics Data System (ADS)

Abd-El-Khalick, Fouad

2013-09-01

The ubiquitous goals of helping precollege students develop informed conceptions of nature of science (NOS) and experience inquiry learning environments that progressively approximate authentic scientific practice have been long-standing and central aims of science education reforms around the globe. However, the realization of these goals continues to elude the science education community partly because of a persistent, albeit not empirically supported, coupling of the two goals in the form of `teaching about NOS with inquiry'. In this context, the present paper aims, first, to introduce the notions of, and articulate the distinction between, teaching with and about NOS, which will allow for the meaningful coupling of the two desired goals. Second, the paper aims to explicate science teachers' knowledge domains requisite for effective teaching with and about NOS. The paper argues that research and development efforts dedicated to helping science teachers develop deep, robust, and integrated NOS understandings would have the dual benefits of not only enabling teachers to convey to students images of science and scientific practice that are commensurate with historical, philosophical, sociological, and psychological scholarship (teaching about NOS), but also to structure robust inquiry learning environments that approximate authentic scientific practice, and implement effective pedagogical approaches that share a lot of the characteristics of best science teaching practices (teaching with NOS).

Play, Make, Know, Keep up, Watch, Dream, and Teach: A Kids-eye View of Climate Change

NASA Astrophysics Data System (ADS)

Fisher, D. K.; Leon, N.; Fitzpatrick, A. J.; Jackson, R.; Greene, M. P.

2012-12-01

No matter the subject, the best way of dealing with doubters or deniers is to present the scientific evidence in a clear, concise, non-threatening, and compelling way. NASA's Climate Kids website--written for upper-elementary age kids and their teachers and parent--explains the basic science behind the evidence that Earth's climate is changing much more rapidly than can be accounted for by natural cycles, and that human activity is responsible. Climate science is complex, and most non-scientists are in what, for some, is the uncomfortable position of accepting scientists at their word. For young children, this is not the best approach to learning. They need to learn to think critically and evaluate the evidence for themselves. Climate Kids debuted in January 2011. It was redesigned and reorganized this year. From the beginning, educator feedback has been very positive. Teachers are grateful to have these difficult concepts simplified, yet still comprehensively covered to present the compelling evidence for anthropogenic global warming and its current and predicted effects. Climate Kids explains the "big questions" of climate science simply and clearly, giving teachers a valuable resource to supplement the science units they normally teach. The site extends science lessons in a very specific way, presenting understandable, real-world examples of scientific evidence of the changes happening on our planet. The new site design organizes content by topic and by type of presentation. Topics are shown in a left-side menu. They are Weather & Climate, Air, Ocean, Fresh Water, Carbon Travels (carbon cycle), Energy, Plants & Animals, and Technology. Presentation types are shown in a top menu. They are Play games, Make stuff (hands-on activities), Know your world (answers to big questions), Catch the latest (climate-related news), Watch videos, Dream of a career (profiles of individuals in green careers), and Teach climate science (resources for educators and parents). So, for

Improving together: collaborative learning in science communication, ClimateSnack case study

NASA Astrophysics Data System (ADS)

Heuzé, C.; Reeve, M. A.

2016-02-01

Most scientists today recognize that science communication is an important part of the scientific process, yet science writing and communication are often taught outside the normal academic schedule. If universities offer such courses, they are generally intensive but short-term: the participants rarely complete a science communication course with an immediate and pressing need to apply these skills. So the skills fade, stalling real progress in science communication. Continuity is key to success! Whilst waiting for the academic system to truly integrate science communication, other methods can be tested. ClimateSnack / SciSnack is a new approach that aims to motivate scientists to develop their communication skills. It adopts a collaborative learning framework where scientists voluntarily form writing groups that meet regularly at different institutes around the world. The members of the groups learn, discuss and improve together. The participants produce short posts, which are published online, where they are further discussed and improved by the global ClimateSnack community. This way, the participants learn and cement basic science communication skills. These skills are transferrable, and can be applied both to scientific articles and broader science media. Some writing groups are highly productive, while others exist no more. The reasons for success are here investigated with respect to issues both internal and external to the different groups, in particular leadership strategies. Possible further development, in particular using the online community, is suggested. ClimateSnack is one solution to fill the critical gap left by a lack of adequate teaching in early-career scientists' curriculum.

Values of Catholic science educators: Their impact on attitudes of science teaching and learning

NASA Astrophysics Data System (ADS)

DeMizio, Joanne Greenwald

This quantitative study examined the associations between the values held by middle school science teachers in Catholic schools and their attitudes towards science teaching. A total of six value types were studied---theoretical, economic, aesthetic, social, political, and religious. Teachers can have negative, positive, or neutral attitudes towards their teaching that are linked to their teaching practices and student learning. These teachers' attitudes may affect their competence and have a subsequent impact on their students' attitudes and dispositions towards science. Of particular interest was the relationship between science teaching attitudes and religious values. A non-experimental research design was used to obtain responses from 54 teachers with two survey instruments, the Science Teaching Attitude Scale II and the Allport-Vernon-Lindzey Study of Values. Stepwise multiple regression analysis showed that political values were negatively associated with attitudes towards science teaching. Data collected were inconsistent with the existence of any measurable association between religious values and attitudes towards science teaching. This study implies that science teacher preparation programs should adopt a more contextual perspective on science that seeks to develop the valuation of science within a cultural context, as well as programs that enable teachers to identify the influence of their beliefs on instructional actions to optimize the impact of learning new teaching practices that may enhance student learning.

Developing Interpretive Power in Science Teaching

ERIC Educational Resources Information Center

Rosebery, Ann S.; Warren, Beth; Tucker-Raymond, Eli

2016-01-01

Early career teachers rarely receive sustained support for addressing issues of diversity and equity in their science teaching. This paper reports on design research to create a 30 hour professional development seminar focused on cultivating the interpretive power of early career teachers who teach science to students from historically…

Advancing Climate Change and Impacts Science Through Climate Informatics

NASA Astrophysics Data System (ADS)

Lenhardt, W.; Pouchard, L. C.; King, A. W.; Branstetter, M. L.; Kao, S.; Wang, D.

2010-12-01

This poster will outline the work to date on developing a climate informatics capability at Oak Ridge National Laboratory (ORNL). The central proposition of this effort is that the application of informatics and information science to the domain of climate change science is an essential means to bridge the realm of high performance computing (HPC) and domain science. The goal is to facilitate knowledge capture and the creation of new scientific insights. For example, a climate informatics capability will help with the understanding and use of model results in domain sciences that were not originally in the scope. From there, HPC can also benefit from feedback as the new approaches may lead to better parameterization in the models. In this poster we will summarize the challenges associated with climate change science that can benefit from the systematic application of informatics and we will highlight our work to date in creating the climate informatics capability to address these types of challenges. We have identified three areas that are particularly challenging in the context of climate change science: 1) integrating model and observational data across different spatial and temporal scales, 2) model linkages, i.e. climate models linked to other models such as hydrologic models, and 3) model diagnostics. Each of these has a methodological component and an informatics component. Our project under way at ORNL seeks to develop new approaches and tools in the context of linking climate change and water issues. We are basing our work on the following four use cases: 1) Evaluation/test of CCSM4 biases in hydrology (precipitation, soil water, runoff, river discharge) over the Rio Grande Basin. User: climate modeler. 2) Investigation of projected changes in hydrology of Rio Grande Basin using the VIC (Variable Infiltration Capacity Macroscale) Hydrologic Model. User: watershed hydrologist/modeler. 3) Impact of climate change on agricultural productivity of the Rio Grande

Contributions of Science Principles to Teaching: How Science Principles Can Be Used

ERIC Educational Resources Information Center

Henson, Kenneth T.

1974-01-01

Describes the steps involved in using the "principles" approach in teaching science, illustrates the process of using science principles with an example relating to rock formation, and discusses the relevance of this approach to contemporary trends in science teaching. (JR)

Science That Matters: Exploring Science Learning and Teaching in Primary Schools

ERIC Educational Resources Information Center

Fitzgerald, Angela; Smith, Kathy

2016-01-01

To help support primary school students to better understand why science matters, teachers must first be supported to teach science in ways that matter. In moving to this point, this paper identifies the dilemmas and tensions primary school teachers face in the teaching of science. The balance is then readdressed through a research-based…

Teaching Planetary Sciences in Bilingual Classrooms

NASA Astrophysics Data System (ADS)

Lebofsky, L. A.; Lebofsky, N. R.

1993-05-01

Planetary sciences can be used to introduce students to the natural world which is a part of their lives. Even children in an urban environment are aware of such phenomena as day and night, shadows, and the seasons. It is a science that transcends cultures, has been prominent in the news in recent years, and can generate excitement in young minds as no other science can. It also provides a useful tool for understanding other sciences and mathematics, and for developing problem solving skills which are important in our technological world. However, only 15 percent of elementary school teachers feel very well qualified to teach earth/space science, while better than 80% feel well qualified to teach reading; many teachers avoid teaching science; very little time is actually spent teaching science in the elementary school: 19 minutes per day in K--3 and 38 minutes per day in 4--6. While very little science is taught in elementary and middle school, earth/space science is taught at the elementary level in less than half of the states. Therefore in order to teach earth/space science to our youth, we must empower our teachers, making them familiar and comfortable with existing materials. Tucson has another, but not unique, problem. The largest public school district, the Tucson Unified School District (TUSD), provides a neighborhood school system enhanced with magnet, bilingual and special needs schools for a school population of 57,000 students that is 4.1% Native American, 6.0% Black, and 36.0% Hispanic (1991). This makes TUSD and the other school districts in and around Tucson ideal for a program that reaches students of diverse ethnic backgrounds. However, few space sciences materials exist in Spanish; most materials could not be used effectively in the classroom. To address this issue, we have translated NASA materials into Spanish and are conducting a series of workshops for bilingual classroom teachers. We will discuss in detail our bilingual classroom workshops

Preservice Science Teachers' Uses of Inscriptions in Science Teaching

ERIC Educational Resources Information Center

Tanis Ozcelik, Arzu; McDonald, Scott P.

2013-01-01

This study investigated preservice science teachers' uses of inscriptions in their peer teaching activities and was guided by the following research questions: (1) What kinds of inscriptions and inscriptional practices do preservice science teachers use in their peer teaching activity? and (2) How and for what purposes do preservice science…

North Central Climate Science Center--science agenda 2012-2017

USGS Publications Warehouse

Morisette, Jeffrey T.

2012-01-01

The information presented here provides the five-year science agenda for the North Central Climate Science Center. It is meant to be a high-level guide that describes the spatial context of the center, the primary partners and stakeholders, and the strategic framework the center will use in applying climate science to inform management.

Teaching Science IBL, a shared experience between schools

NASA Astrophysics Data System (ADS)

Ruas, Fatima; Carneiro, Paula

2015-04-01

Key words: Problem based learning, Inquiry-based learning, digital resources, climate changes The inquiry-based learning approach is applied by watching a video about the last rigorous winter and its effects. The teacher starts by posing some questions related with the video news: Why only after a 20 or 30 years from now, how will it be possible to explain the occurrence of two storms in just a month's time? Is our climate effectively changing? What is the difference between weather and climate? The teacher helps students to think about where and how they can find information about the subject, providing/teaching them suitable tools to access and use information. The teacher plays the role of mentor/facilitator. Students should proceed to their research, presenting the results to their colleagues, discussing in groups, doing brainstorming and collaborate in the learning process. After the discussion the students must present their conclusions. The main goals are: explain the difference between weather and climate; understand whether or not climate change exists; identify the causes of climate change and extreme weather events; raising awareness among young people about environmental issues of preservation and sustainability of our planet. The results globally show that this educational approach motivates students' towards science, helping them to solve problems from daily life, as well as the collaborative working. The cognitive strand continues to be the most valued by pupils.

Newly qualified teachers' visions of science learning and teaching

NASA Astrophysics Data System (ADS)

Roberts, Deborah L.

2011-12-01

This study investigated newly qualified teachers' visions of science learning and teaching. The study also documented their preparation in an elementary science methods course. The research questions were: What educational and professional experiences influenced the instructor's visions of science learning and teaching? What visions of science learning and teaching were promoted in the participants' science methods course? What visions of science learning and teaching did these newly qualified teachers bring with them as they graduated from their teacher preparation program? How did these visions compare with those advocated by reform documents? Data sources included participants' assignments, weekly reflections, and multi-media portfolio finals. Semi-structured interviews provided the emic voice of participants, after graduation but before they had begun to teach. These data were interpreted via a combination of qualitative methodologies. Vignettes described class activities. Assertions supported by excerpts from participants' writings emerged from repeated review of their assignments. A case study of a typical participant characterized weekly reflections and final multi-media portfolio. Four strands of science proficiency articulated in a national reform document provided a framework for interpreting activities, assignments, and interview responses. Prior experiences that influenced design of the methods course included an inquiry-based undergraduate physics course, participation in a reform-based teacher preparation program, undergraduate and graduate inquiry-based science teaching methods courses, participation in a teacher research group, continued connection to the university as a beginning teacher, teaching in diverse Title 1 schools, service as the county and state elementary science specialist, participation in the Carnegie Academy for the Scholarship of Teaching and Learning, service on a National Research Council committee, and experience teaching a

Teaching a Relational Approach to Climate Change: Working with People and Conflict

NASA Astrophysics Data System (ADS)

Kearns, F.

2015-12-01

In 2010, science and technology studies expert Sheila Jasanoff concluded an article in Science by observing that the scientific community "…has demonstrated that it can learn and change in its methods of representing science to scientists. That ingenuity should now be directed toward building relationships of trust and respect with the global citizens whose future climate science has undertaken to predict and reshape." This kind of statement indicates a large shift in the focus on climate-related work, in a sense concluding that the scientific conclusions are well-established, but there is a human-to-human, relationship-based element of the work that needs attention. At the same time, there is increasing emphasis on transitioning to more participatory models of research, practice, and engagement in climate work, the human relationships that underlie these approaches are rarely explicitly addressed. For example, conflict, a key relational process, is often an inevitable element of engagement in societal processes. Although conflict can lead toward more successful long-term solutions if addressed constructively, dealing with it can be highly uncomfortable on an individual level and is often avoided. Acknowledging the often pivotal role conflict plays in eventual solutions bolsters the notion of complementing current training with a focus on relationship building. Professional development to increase relational capacity is being adopted in fields such as law and medicine; these same approaches are also increasingly relevant for climate practitioners where strong emotions such as grief and anxiety are often present for both practitioners and those they interact with. A framework for teaching and learning to effectively interact in this rich, relational world will be presented.

Strategies for Teaching Regional Climate Modeling: Online Professional Development for Scientists and Decision Makers

NASA Astrophysics Data System (ADS)

Walton, P.; Yarker, M. B.; Mesquita, M. D. S.; Otto, F. E. L.

2014-12-01

There is a clear role for climate science in supporting decision making at a range of scales and in a range of contexts: from Global to local, from Policy to Industry. However, clear a role climate science can play, there is also a clear discrepancy in the understanding of how to use the science and associated tools (such as climate models). Despite there being a large body of literature on the science there is clearly a need to provide greater support in how to apply appropriately. However, access to high quality professional development courses can be problematic, due to geographic, financial and time constraints. In attempt to address this gap we independently developed two online professional courses that focused on helping participants use and apply two regional climate models, WRF and PRECIS. Both courses were designed to support participants' learning through tutor led programs that covered the basic climate scientific principles of regional climate modeling and how to apply model outputs. The fundamental differences between the two courses are: 1) the WRF modeling course expected participants to design their own research question that was then run on a version of the model, whereas 2) the PRECIS course concentrated on the principles of regional modeling and how the climate science informed the modeling process. The two courses were developed to utilise the cost and time management benefits associated with eLearning, with the recognition that this mode of teaching can also be accessed internationally, providing professional development courses in countries that may not be able to provide their own. The development teams saw it as critical that the courses reflected sound educational theory, to ensure that participants had the maximum opportunity to learn successfully. In particular, the role of reflection is central to both course structures to help participants make sense of the science in relation to their own situation. This paper details the different

The concept of nature in Islamic science teaching

NASA Astrophysics Data System (ADS)

Zarman, Wendi

2016-02-01

Science teaching is basically value laden activities. One of the values tells that science is not related to any religion. This secular value is reflected to science teaching in many places, including religious country like Indonesia. However, we argue that in Indonesia science teaching should not be secular as in the Western country since one of the basic aim of National Education according to the Indonesian constitution Undang-Undang Dasar 1945, is to inculcate faith and god-fearing to One God Almighty. As we know, Indonesia is a Moslem country and has many Islamic schools in it too. Thus, it is important to design a science teaching framework base on Islamic teaching to fulfill the basic aim of National Education This paper discusses concept of nature, the key term in science, based on Islamic view that may used as a framework to develop Islamic science teaching. In Islam, science has a strong relation to religion since nature reflects the existence of the Creator. This concept is derived from the analysis of several verses from Qur'an as the main source of Islamic teaching. There are several principle can be derived from this analysis. Firstly, visible world is not the only world, but there is also the unseen world. Secondly, the nature is not merely matter that doesn't have any sacred value, but it is the indication or symbol of God existence and His Nature. Thirdly, The Qur'an and the nature are both Books of Allah that contain messages of Him, so they are complementary to each other

Teaching science in museums

NASA Astrophysics Data System (ADS)

Tran, Lynn Uyen

Museums are free-choice, non-threatening, non-evaluative learning and teaching environments. They enable learners to revisit contents, authentic objects, and experiences at their own leisure as they continually build an understanding and appreciation of the concepts. Schools in America have used museums as resources to supplement their curriculum since the 19 th century. Field trip research is predominantly from the teachers' and students' perspectives, and draws attention to the importance for classroom teachers and students to prepare prior to field trips, have tasks, goals, and objectives during their time at the museum, and follow up afterwards. Meanwhile, museum educators' contributions to field trip experiences have been scantily addressed. These educators develop and implement programs intended to help students' explore science concepts and make sense of their experiences, and despite their limited time with students, studies show they can be memorable. First, field trips are a break in the usual routine, and thus have curiosity and attention attracting power. Second, classroom science teaching literature suggests teachers' teaching knowledge and goals can affect their behaviors, and in turn influence student learning. Third, classroom teachers are novices at planning and implementing field trip planners, and museum educators can share this responsibility. But little is reported on how the educators teach, what guides their instruction, how classroom teachers use these lessons, and what is gained from these lessons. This study investigates two of these inquiries. The following research questions guided this investigation. (1) How do educators teaching one-hour, one-time lessons in museums adapt their instruction to the students that they teach? (2) How do time limitations affect instruction? (3) How does perceived variability in entering student knowledge affect instruction? Four educators from two museums took part in this participant observation study to

Sink or Swim: The Climate for Teaching as Viewed by Award-Winning Teachers

ERIC Educational Resources Information Center

Smith, Justin M.

2013-01-01

This study explores the climate for teaching at a major Midwest research university. Teaching climate is generally defined as the shared perceptions of current organizational processes that affect the institutional environment for teaching (Peterson et al., 1991; Tagiuri, 1968). Three types of distinguished teaching awards were used to select…

A longitudinal investigation of the preservice science teachers' beliefs about science teaching during a science teacher training programme

NASA Astrophysics Data System (ADS)

Buldur, Serkan

2017-01-01

The aim of this longitudinal study was to investigate the changes in preservice science teachers' beliefs about science teaching during a science teacher training programme. The study was designed as a panel study, and the data were collected from the same participants at the end of each academic year during a four-year period. The participants were composed of 76 preservice teachers, and the DASTT-C was used as the data collection tool. As a result of the study, it was determined that the students had conventional teaching beliefs after the first years of the teacher training programme. Moreover, the mental teaching styles of preservice teachers about the science teaching were found to undergo changes throughout their undergraduate education. Participants' beliefs about conventional teaching started to change, especially after they first took a science method course in their third year and their beliefs shifted towards student-centred teaching. Implications for science teacher training programmes were also addressed.

Word diffusion and climate science.

PubMed

Bentley, R Alexander; Garnett, Philip; O'Brien, Michael J; Brock, William A

2012-01-01

As public and political debates often demonstrate, a substantial disjoint can exist between the findings of science and the impact it has on the public. Using climate-change science as a case example, we reconsider the role of scientists in the information-dissemination process, our hypothesis being that important keywords used in climate science follow "boom and bust" fashion cycles in public usage. Representing this public usage through extraordinary new data on word frequencies in books published up to the year 2008, we show that a classic two-parameter social-diffusion model closely fits the comings and goings of many keywords over generational or longer time scales. We suggest that the fashions of word usage contributes an empirical, possibly regular, correlate to the impact of climate science on society.

How to Justify Teaching False Science

ERIC Educational Resources Information Center

Slater, Matthew H.

2008-01-01

We often knowingly teach false science. Such a practice conflicts with a prima facie pedagogical value placed on teaching only what is true. I argue that only a partial dissolution of the conflict is possible: the proper aim of instruction in science is not to provide an armory of facts about what things the world contains, how they interact, and…

Safety and Science Teaching.

ERIC Educational Resources Information Center

Virginia State Dept. of Education, Richmond. Div. of Sciences and Elementary Administration.

This 10-chapter handbook (designed for science teachers and school administrators) describes known hazards associated with science teaching and provides information to develop a framework for local safety programs specifically designed to avoid or neutralize the effects of such hazards. Major areas addressed in the chapters include: (1) the nature…

Exploring the Place of Exemplary Science Teaching. This Year in School Science 1993.

ERIC Educational Resources Information Center

Haley-Oliphant, Ann E., Ed.

Exemplary science teaching is an experience that fosters wonder, excitement, and risk-taking. This book presents essays which attempt to describe the culture of classrooms of exemplary science teachers. Chapter titles are: "Exploring the Place of Exemplary Science Teaching" (Ann E. Haley-Oliphant); "The Voices of Exemplary Science Teachers" (Ann…

Reform-based science teaching: A mixed-methods approach to explaining variation in secondary science teacher practice

NASA Astrophysics Data System (ADS)

Jetty, Lauren E.

The purpose of this two-phase, sequential explanatory mixed-methods study was to understand and explain the variation seen in secondary science teachers' enactment of reform-based instructional practices. Utilizing teacher socialization theory, this mixed-methods analysis was conducted to determine the relative influence of secondary science teachers' characteristics, backgrounds and experiences across their teacher development to explain the range of teaching practices exhibited by graduates from three reform-oriented teacher preparation programs. Data for this study were obtained from the Investigating the Meaningfulness of Preservice Programs Across the Continuum of Teaching (IMPPACT) Project, a multi-university, longitudinal study funded by NSF. In the first quantitative phase of the study, data for the sample (N=120) were collected from three surveys from the IMPPACT Project database. Hierarchical multiple regression analysis was used to examine the separate as well as the combined influence of factors such as teachers' personal and professional background characteristics, beliefs about reform-based science teaching, feelings of preparedness to teach science, school context, school culture and climate of professional learning, and influences of the policy environment on the teachers' use of reform-based instructional practices. Findings indicate three blocks of variables, professional background, beliefs/efficacy, and local school context added significant contribution to explaining nearly 38% of the variation in secondary science teachers' use of reform-based instructional practices. The five variables that significantly contributed to explaining variation in teachers' use of reform-based instructional practices in the full model were, university of teacher preparation, sense of preparation for teaching science, the quality of professional development, science content focused professional, and the perceived level of professional autonomy. Using the results

Cognitive-based approach in teaching 1st year Physics for Life Sciences, including Atmospheric Physics and Climate Change components

NASA Astrophysics Data System (ADS)

Petelina, S. V.

2009-12-01

Most 1st year students who take the service course in Physics - Physics for Life Sciences - in Australia encounter numerous problems caused by such factors as no previous experience with this subject; general perception that Physics is hard and only very gifted people are able to understand it; lack of knowledge of elementary mathematics; difficulties encountered by lecturers in teaching university level Physics to a class of nearly 200 students with no prior experience, diverse and sometime disadvantageous backgrounds, different majoring areas, and different learning abilities. As a result, many students either drop, or fail the subject. In addition, many of those who pass develop a huge dislike towards Physics, consider the whole experience as time wasted, and spread this opinion among their peers and friends. The above issues were addressed by introducing numerous changes to the curriculum and modifying strategies and approaches in teaching Physics for Life Sciences. Instead of a conventional approach - teaching Physics from simple to complicated, topic after topic, the students were placed in the world of Physics in the same way as a newborn child is introduced to this world - everything is seen all the time and everywhere. That created a unique environment where a bigger picture and all details were always present and interrelated. Numerous concepts of classical and modern physics were discussed, compared, and interconnected all the time with “Light” being a key component. Our primary field of research is Atmospheric Physics, in particular studying the atmospheric composition and structure using various satellite and ground-based data. With this expertise and also inspired by an increasing importance of training a scientifically educated generation who understands the challenges of the modern society and responsibilities that come with wealth, a new section on environmental physics has been developed. It included atmospheric processes and the greenhouse

Teaching and Learning Science for Transformative, Aesthetic Experience

NASA Astrophysics Data System (ADS)

Girod, Mark; Twyman, Todd; Wojcikiewicz, Steve

2010-11-01

Drawing from the Deweyan theory of experience (1934, 1938), the goal of teaching and learning for transformative, aesthetic experience is contrasted against teaching and learning from a cognitive, rational framework. A quasi-experimental design was used to investigate teaching and learning of fifth grade science from each perspective across an entire school year including three major units of instruction. Detailed comparisons of teaching are given and pre and post measures of interest in learning science, science identity affiliation, and efficacy beliefs are investigated. Tests of conceptual understanding before, after, and one month after instruction reveal teaching for transformative, aesthetic experience fosters more, and more enduring, learning of science concepts. Investigations of transfer also suggest students learning for transformative, aesthetic experiences learn to see the world differently and find more interest and excitement in the world outside of school.

Fostering Hope in Climate Change Educators

ERIC Educational Resources Information Center

Swim, Janet K.; Fraser, John

2013-01-01

Climate Change is a complex set of issues with large social and ecological risks. Addressing it requires an attentive and climate literate population capable of making informed decisions. Informal science educators are well-positioned to teach climate science and motivate engagement, but many have resisted the topic because of self-doubt about…

Innovations in College Science Teaching.

ERIC Educational Resources Information Center

Penick, John E., Ed.; Dunkhase, John A., Ed.

Fifteen innovative college science programs based on survey results about perceptions of excellence in college science teaching are presented. The goals, program origins, special features of the programs, evaluations, and conclusions are described for each. Discussed are the commonalities among this collection of 15 college science programs and…

The effect of teacher education level, teaching experience, and teaching behaviors on student science achievement

NASA Astrophysics Data System (ADS)

Zhang, Danhui

Previous literature leaves us unanswered questions about whether teaching behaviors mediate the relationship between teacher education level and experience with student science achievement. This study examined this question with 655 students from sixth to eighth grade and their 12 science teachers. Student science achievements were measured at the beginning and end of 2006-2007 school year. Given the cluster sampling of students nested in classrooms, which are nested in teachers, a two-level multilevel model was employed to disentangle the effects from teacher-level and student-level factors. Several findings were discovered in this study. Science teachers possessing of advanced degrees in science or education significantly and positively influenced student science achievement. However, years of teaching experience in science did not directly influence student science achievement. A significant interaction was detected between teachers possessing an advanced degree in science or education and years of teaching science, which was inversely associated to student science achievement. Better teaching behaviors were also positively related to student achievement in science directly, as well as mediated the relationship between student science achievement and both teacher education and experience. Additionally, when examined separately, each teaching behavior variable (teacher engagement, classroom management, and teaching strategies) served as a significant intermediary between both teacher education and experience and student science achievement. The findings of this study are intended to provide insights into the importance of hiring and developing qualified teachers who are better able to help students achieve in science, as well as to direct the emphases of ongoing teacher inservice training.

Collaborative activities for improving the quality of science teaching and learning and learning to teach science

NASA Astrophysics Data System (ADS)

Tobin, Kenneth

2012-03-01

I have been involved in research on collaborative activities for improving the quality of teaching and learning high school science. Initially the collaborative activities we researched involved the uses of coteaching and cogenerative dialogue in urban middle and high schools in Philadelphia and New York (currently I have active research sites in New York and Brisbane, Australia). The research not only transformed practices but also produced theories that informed the development of additional collaborative activities and served as interventions for research and creation of heuristics for professional development programs and teacher certification courses. The presentation describes a collage of collaborative approaches to teaching and learning science, including coteaching, cogenerative dialogue, radical listening, critical reflection, and mindful action. For each activity in the collage I provide theoretical frameworks and empirical support, ongoing research, and priorities for the road ahead. I also address methodologies used in the research, illustrating how teachers and students collaborated as researchers in multilevel investigations of teaching and learning and learning to teach that included ethnography, video analysis, and sophisticated analyses of the voice, facial expression of emotion, eye gaze, and movement of the body during classroom interactions. I trace the evolution of studies of face-to-face interactions in science classes to the current focus on emotions and physiological aspects of teaching and learning (e.g., pulse rate, pulse strength, breathing patterns) that relate to science participation and achievement.

Enhancing the Communication of Climate Change Science

NASA Astrophysics Data System (ADS)

Somerville, R. C.; Hassol, S. J.

2011-12-01

Climate scientists have an important role to play in the critical task of informing the public, media and policymakers. Scientists can help in publicizing and illuminating climate science. However, this task requires combining climate science expertise with advanced communication skills. For example, it is entirely possible to convey scientific information accurately without using jargon or technical concepts unfamiliar to non-scientists. However, making this translation into everyday language is a job that few scientists have been trained to do. In this talk, we give examples from our recent experience working with scientists to enhance their ability to communicate well. Our work includes providing training, technical assistance, and communications tools to climate scientists and universities, government agencies, and research centers. Our experience ranges from preparing Congressional testimony to writing major climate science reports to appearing on television. We have also aided journalists in gathering reliable scientific information and identifying trustworthy experts. Additionally, we are involved in developing resources freely available online at climatecommunication.org. These include a feature on the links between climate change and extreme weather, a climate science primer, and graphics and video explaining key developments in climate change science.

Effect of the learning climate of residency programs on faculty's teaching performance as evaluated by residents.

PubMed

Lombarts, Kiki M J M H; Heineman, Maas Jan; Scherpbier, Albert J J A; Arah, Onyebuchi A

2014-01-01

To understand teaching performance of individual faculty, the climate in which residents' learning takes place, the learning climate, may be important. There is emerging evidence that specific climates do predict specific outcomes. Until now, the effect of learning climate on the performance of the individual faculty who actually do the teaching was unknown. THIS STUDY: (i) tested the hypothesis that a positive learning climate was associated with better teaching performance of individual faculty as evaluated by residents, and (ii) explored which dimensions of learning climate were associated with faculty's teaching performance. We conducted two cross-sectional questionnaire surveys amongst residents from 45 residency training programs and multiple specialties in 17 hospitals in the Netherlands. Residents evaluated the teaching performance of individual faculty using the robust System for Evaluating Teaching Qualities (SETQ) and evaluated the learning climate of residency programs using the Dutch Residency Educational Climate Test (D-RECT). The validated D-RECT questionnaire consisted of 11 subscales of learning climate. Main outcome measure was faculty's overall teaching (SETQ) score. We used multivariable adjusted linear mixed models to estimate the separate associations of overall learning climate and each of its subscales with faculty's teaching performance. In total 451 residents completed 3569 SETQ evaluations of 502 faculty. Residents also evaluated the learning climate of 45 residency programs in 17 hospitals in the Netherlands. Overall learning climate was positively associated with faculty's teaching performance (regression coefficient 0.54, 95% confidence interval: 0.37 to 0.71; P<0.001). Three out of 11 learning climate subscales were substantially associated with better teaching performance: 'coaching and assessment', 'work is adapted to residents' competence', and 'formal education'. Individual faculty's teaching performance evaluations are positively

Teaching science as argument: Prospective elementary teachers' knowledge

NASA Astrophysics Data System (ADS)

Barreto-Espino, Reizelie

For the past two decades there has been increasing emphasis on argumentation in school science. In 2007, the National Research Council published a synthesis report that emphasizes the centrality of constructing, evaluating, and using scientific explanations. Participating in argumentation is seen as fundamental to children's science learning experiences. These new expectations increase challenges for elementary teachers since their understanding of and experiences with science are overwhelmingly inconsistent with teaching science as argument. These challenges are further amplified when dealing with prospective elementary teachers. The current study was guided by the following research questions: (1) What are the ways in which preservice elementary teachers appropriate components of "teaching science as argument" during their student teaching experience? (2) To what extent do components from prospective elementary teachers' reflections influence planning for science teaching? (3) What elements from the context influence preservice elementary teachers' attention to teaching science as argument? This study followed a multi-participant case study approach and analyses were informed by grounded theory. Three participants were selected from a larger cohort of prospective elementary teachers enrolled in an innovative Elementary Professional Development School (PDS) partnership at a large Northeast University. Cross-case analysis allowed for the development of five key assertions: (1) The presence of opportunities for interacting with phenomena and collecting first hand data helped participants increase their emphasis on evidence-based explanations. (2) Participants viewed science talks as an essential mechanism for engaging students in the construction of evidence-based explanations and as being fundamental to meaning-making. (3) Participants demonstrated attention to scientific subject matter during instruction rather than merely focusing on activities and/or inquiry

Turkish preservice science teachers' socioscientific issues-based teaching practices in middle school science classrooms

NASA Astrophysics Data System (ADS)

Genel, Abdulkadir; Sami Topçu, Mustafa

2016-01-01

Background: Despite a growing body of research and curriculum reforms including socioscientific issues (SSI) across the world, how preservice science teachers (PST) or in-service science teachers can teach SSI in science classrooms needs further inquiry. Purpose: The purpose of this study is to describe the abilities of PSTs to teach SSI in middle school science classrooms, and the research question that guided the present study is: How can we characterize Turkish PSTs' SSI-based teaching practices in middle school science classrooms (ages 11-14)? Sample: In order to address the research question of this study, we explored 10 Turkish PSTs' SSI-based teaching practices in middle school science classrooms. A purposeful sampling strategy was used, thus, PSTs were specifically chosen because they were ideal candidates to teach SSI and to integrate SSI into the science curricula since they were seniors in the science education program who had to take the field experience courses. Design and method: The participants' SSI teaching practices were characterized in light of qualitative research approach. SSI-based teaching practices were analyzed, and the transcripts of all videotape recordings were coded by two researchers. Results: The current data analysis describes Turkish PSTs' SSI-based teaching practices under five main categories: media, argumentation, SSI selection and presentation, risk analysis, and moral perspective. Most of PSTs did not use media resources in their lesson and none of them considered moral perspective in their teaching. While the risk analyses were very simple and superficial, the arguments developed in the classrooms generally remained at a simple level. PSTs did not think SSI as a central topic and discussed these issues in a very limited time and at the end of the class period. Conclusions: The findings of this study manifest the need of the reforms in science education programs. The present study provides evidence that moral, media

Teaching Science through Physical Education.

ERIC Educational Resources Information Center

Kumar, David; Whitehurst, Michael

1997-01-01

Physical education can serve as a vehicle for teaching science and make student understanding of certain personal health-related science concepts meaningful. Describes activities involving the musculoskeletal system, the nervous system, and the cardiovascular system. (DKM)

Measuring and Improving the Climate for Teaching: A Multi-Year Study

ERIC Educational Resources Information Center

Lyon, Julie S.; Gettman, Hilary J.; Roberts, Scott P.; Shaw, Cynthia E.

2015-01-01

All organizations have "climates" that significantly affect their employees' performance and satisfaction. The authors posit that an academic department's "climate for teaching" (CFT)--or the the extent to which excellent teaching is rewarded, supported, and expected--has a profound impact on the experience of its instructors…

Teaching Science to the Gifted.

ERIC Educational Resources Information Center

Scher, Joyce L.

Science teaching practices at the Long Island School for the Gifted emphasize hands-on experiments where children do the work and the teacher assists learning. This approach bypasses the reading/writing barrier that prevents some children from learning science. Many science experiments are described, including a first-grade lesson on using…

Preservice Elementary Teachers' Beliefs about Science Teaching

ERIC Educational Resources Information Center

Yilmaz-Tuzun, Ozgul

2008-01-01

In this study, a Beliefs About Teaching (BAT) scale was created to examine preservice elementary science teachers' self-reported comfort level with both traditional and reform-based teaching methods, assessment techniques, classroom management techniques, and science content. Participants included 166 preservice teachers from three different US…

Developing and testing multimedia educational tools to teach Polar Sciences in the Italian school

NASA Astrophysics Data System (ADS)

Macario, Maddalena; Cattadori, Matteo; Bianchi, Cristiana; Zattin, Massimiliano; Talarico, Franco Maria

2013-04-01

In the last few years science education moved forward rapidly by connecting the expertise and enthusiasm of polar educators worldwide. The interest in Polar Sciences determined the creation of a global professional network for those that educate in, for, and about the Polar Regions. In Italy, this cooperation is well represented by APECS-Italy, the Italian section of the Association of Polar Early Career Scientists (APECS) that is composed by young researchers and teachers of the Italian School. The Polar Regions represent one of the best natural environments where students can investigate directly on global changes. In this sense, the working group UNICAMearth of the Geology Division of School of Science and Technology, University of Camerino (Italy), promotes the arrangement of instructional resources based on real data coming from the research world. Our project aims to develop innovative teaching resources and practices designed to bring the importance of the Polar Regions closer to home. Consequently, Polar Sciences could become a focus point in the new national school curricula, where Earth Sciences have to be thought and learnt in an integrated way together with other sciences. In particular, M. Macario is producing a teaching tool package, starting from a case study, which includes a dozen of full lesson plans based on multimedia tools (images, smart board lessons and videos of lab experiments) as well as on hands-on activities about polar issues and phenomena. Among the resources the teaching tool package is referring to, there is also an App for tablet named CLAST (CLimate in Antartica from Sediments and Tectonics). This App has been designed by a team made up of polar scientists belonging to the University of Siena and University of Padova, two science teachers of the Museo delle Scienze (MUSE) of Trento other than M. Macario. CLAST has been funded by two Research Projects, CLITEITAM ("CLImate-TEctonics Interactions along the TransAntarctic Mountains

Using narratives to motivate climate science

NASA Astrophysics Data System (ADS)

Stiller-Reeve, Mathew; Bremer, Scott; Blanchard, Anne

2015-04-01

This paper presents the lessons learnt by the climate scientists within an interdisciplinary research project called 'TRACKS': Transforming climate knowledge with and for society. The project uses the climate narratives of local people in northeast Bangladesh as a basis for mobilizing high quality climate knowledge for adaptation. To ensure this high quality climate information, the project demands an interdisciplinary approach. This project is therefore a broad, but tight collaboration between climate science and perspectives from social science and the humanities. For the climate scientists involved, the aim was to do research that would provide local people with climate information that would hopefully aid adaptation. The climate research design had to consider the perceptions of the local people in northeast Bangladesh, and what aspects of the local climate that they thought were important. For the climate scientists to gain an appropriate understanding, they were fully integrated into the whole narrative research process. The different disciplines cooperate fully in all aspects of the TRACKS project. The climate scientists were involved in planning the narrative interview survey about weather and how it impacts the lives of local people in northeast Bangladesh. The climate scientists participated in a workshop with social science colleagues from Bangladesh and Norway, to design the research questions, the interview framework, and the data management plan. The climate scientists then travelled to Bangladesh with social scientist colleagues to observe and discuss ten pilot interviews with local people, and to take part in two 'stakeholder-mapping' workshops. On the basis of these interviews and workshops, the climate scientists arranged an interdisciplinary workshop where all the project's researchers designed the climate science research questions together. The climate research questions have therefore been built around a first-hand interdisciplinary experience

Improving Early Career Science Teachers' Ability to Teach Space Science

NASA Astrophysics Data System (ADS)

Schultz, G. R.; Slater, T. F.; Wierman, T.; Erickson, J. G.; Mendez, B. J.

2012-12-01

The GEMS Space Science Sequence is a high quality, hands-on curriculum for elementary and middle schools, created by a national team of astronomers and science educators with NASA funding and support. The standards-aligned curriculum includes 24 class sessions for upper elementary grades targeting the scale and nature of Earth's, shape, motion and gravity, and 36 class sessions for middle school grades focusing on the interactions between our Sun and Earth and the nature of the solar system and beyond. These materials feature extensive teacher support materials which results in pre-test to post-test content gains for students averaging 22%. Despite the materials being highly successful, there has been a less than desired uptake by teachers in using these materials, largely due to a lack of professional development training. Responding to the need to improve the quantity and quality of space science education, a collaborative of space scientists and science educators - from the University of California, Berkeley's Lawrence Hall of Science (LHS) and Center for Science Education at the Space Sciences Laboratory (CSE@SSL), the Astronomical Society of the Pacific (ASP), the University of Wyoming, and the CAPER Center for Astronomy & Physics Education - experimented with a unique professional development model focused on helping master teachers work closely with pre-service teachers during their student teaching internship field experience. Research on the exodus of young teachers from the teaching profession clearly demonstrates that early career teachers often leave teaching because of a lack of mentoring support and classroom ready curriculum materials. The Advancing Mentor and Novice Teachers in Space Science (AMANTISS) team first identified master teachers who supervise novice, student teachers in middle school, and trained these master teachers to use the GEMS Space Science Sequence for Grades 6-8. Then, these master teachers were mentored in how to coach their

Teaching Science through Story

ERIC Educational Resources Information Center

Horton, Jessica

2013-01-01

Children find comfort in stories. They are familiar, accessible and entertaining. By teaching science through narratives, we can provide that same comfort and access to scientific content to children of all ages. In this article, I will discuss how, through the use of narratives in science instruction, we can provide students with a deeper…

Inspiring Climate Education Excellence (ICEE): Developing self-directed professional development modules for secondary science teachers

NASA Astrophysics Data System (ADS)

Buhr, S. M.; Lynds, S. E.; McCaffrey, M. S.; Morton, E.

2010-12-01

Inspiring Climate Education Excellence (ICEE) is a NASA-funded project to develop online course modules and self-directed learning resources aligned with the Essential Principles of Climate Science. Following a national needs assessment survey and a face to face workshop to pilot test topics, a suite of online modules is being developed suitable for self-directed learning by secondary science teachers. Modules are designed around concepts and topics in which teachers express the most interest and need for instruction. Module design also includes attention to effective teaching strategies, such as awareness of student misconceptions, strategies for forestalling controversy and advice from master teachers on implementation and curriculum development. The resources are being developed in partnership with GLOBE, and the National Science Digital Library (NSDL) and is informed by the work of the Climate Literacy and Energy Awareness Network (CLEAN) project. ICEE will help to meet the professional development needs of teachers, including those participating in the GLOBE Student Climate Research Campaign. Modules and self-directed learning resources will be developed and disseminated in partnership with the National Science Digital Library (NSDL). This presentation introduces the needs assessment and pilot workshop data upon which the modules are based, and describes the modules that are available and in development.

Crossing borders: High school science teachers learning to teach the specialized language of science

NASA Astrophysics Data System (ADS)

Patrick, Jennifer Drake

The highly specialized language of science is both challenging and alienating to adolescent readers. This study investigated how secondary science teachers learn to teach the specialized language of science in their classrooms. Three research questions guided this study: (a) what do science teachers know about teaching reading in science? (b) what understanding about the unique language demands of science reading do they construct through professional development? and (c) how do they integrate what they have learned about these specialized features of science language into their teaching practices? This study investigated the experience of seven secondary science teachers as they participated in a professional development program designed to teach them about the specialized language of science. Data sources included participant interviews, audio-taped professional development sessions, field notes from classroom observations, and a prior knowledge survey. Results from this study suggest that science teachers (a) were excited to learn about disciplinary reading practices, (b) developed an emergent awareness of the specialized features of science language and the various genres of science writing, and (c) recognized that the challenges of science reading goes beyond vocabulary. These teachers' efforts to understand and address the language of science in their teaching practices were undermined by their lack of basic knowledge of grammar, availability of time and resources, their prior knowledge and experiences, existing curriculum, and school structure. This study contributes to our understanding of how secondary science teachers learn about disciplinary literacy and apply that knowledge in their classroom instruction. It has important implications for literacy educators and science educators who are interested in using language and literacy practices in the service of science teaching and learning. (Full text of this dissertation may be available via the University

Hot Topics in Science Teaching

ERIC Educational Resources Information Center

Ediger, Marlow

2018-01-01

There are vital topics in science teaching and learning which are mentioned frequently in the literature. Specialists advocate their importance in the curriculum as well as science teachers stress their saliency. Inservice education might well assist new and veteran teachers in knowledge and skills. The very best science lessons and units of…

Study of Turkish Preschool Teachers' Attitudes toward Science Teaching

NASA Astrophysics Data System (ADS)

Erden, Feyza T.; Sönmez, Sema

2011-05-01

This study aims to explore preschool teachers' attitudes toward science teaching and its impact on classroom practices through the frequency of science activities provided in the classroom. In addition, the study investigates if their attitudes are related to factors such as educational level, years of teaching experience, and the school type they work in. The present research was conducted with 292 preschool teachers who work in public and private schools in different districts of Ankara, Turkey. The data were collected by administering the Early Childhood Teachers' Attitudes toward Science Teaching Scale. Our analyses indicate that there is a significant but weak link between preschool teachers' attitudes toward science teaching and the frequency of science activities that they provide in the classroom. Further, while teachers' characteristics such as educational level and experience are found to play an insignificant role on the overall measures of the scale, type of school appears to be a major factor in explaining the attitudes toward science teaching.

Pre-service elementary science teaching self-efficacy and teaching practices: A mixed-methods, dual-phase, embedded case study

NASA Astrophysics Data System (ADS)

Sangueza, Cheryl Ramirez

This mixed-method, dual-phase, embedded-case study employed the Social Cognitive Theory and the construct of self-efficacy to examine the contributors to science teaching self-efficacy and science teaching practices across different levels of efficacy in six pre-service elementary teachers during their science methods course and student teaching experiences. Data sources included the Science Teaching Efficacy Belief Instrument (STEBI-B) for pre-service teachers, questionnaires, journals, reflections, student teaching lesson observations, and lesson debriefing notes. Results from the STEBI-B show that all participants measured an increase in efficacy throughout the study. The ANOVA analysis of the STEBI-B revealed a statistically significant increase in level of efficacy during methods course, student teaching, and from the beginning of the study to the end. Of interest in this study was the examination of the participants' science teaching practices across different levels of efficacy. Results of this analysis revealed how the pre-service elementary teachers in this study contextualized their experiences in learning to teach science and its influences on their science teaching practices. Key implications involves the value in exploring how pre-service teachers interpret their learning to teach experiences and how their interpretations influence the development of their science teaching practices.

Partners in Earth System Science: a Field, Laboratory and Classroom Based Professional Development Program for K-12 Teachers Designed to Build Scientific and Pedagogical Understandings of Teaching Climate Change.

NASA Astrophysics Data System (ADS)

Slattery, W.; Lunsford, S.; Diedrick, A.; Crane, C.

2015-12-01

The purpose of the Partners in Earth System Science summer and academic year professional development program for Ohio K-12 teachers is to build their understandings of the scientific observations, methods and resources that scientists use when studying past and present climate change. Participants then use these tools to develop inquiry-based activities to teach their K-12 students how the scientific method and data are used to understand the effects of global climate change. The summer portion of the program takes teachers from throughout Ohio to the Duke University Marine Laboratory in Beaufort, North Carolina. There they engage in a physical and biological exploration of the modern and ancient ocean. For example, they collect samples of sediment and test water samples collected from modern coastal environments and connect their findings with evidence of the fauna living in those environments. Then, using observations from the geological record of the Eocene through Pleistocene sediments exposed in eastern North Carolina and inferences from observations made from the modern ocean they seek to answer scientifically testable questions regarding the physical and biological characteristics of the ocean during Cenozoic climate change events. During the academic year participants connect with each other and project faculty online to support the development of inquiry based science activities for their K-12 students. These activities focus on how evidence and observations such as outcrop extent, sediment type and biological assemblages can be used to infer past climates. The activities are taught in participant's classrooms and discussed with other participants in an online discussion space. Assessment of both teachers and K-12 students document significant positive changes in science knowledge, their confidence in being able to do science and a clearer understanding of how oceans are impacted by global climate change.

Learning to teach science in a professional development school program

NASA Astrophysics Data System (ADS)

Hildreth, David P.

1997-09-01

The purpose of this study was to determine the effects of learning to teach science in a Professional Development School (PDS) program on university elementary education preservice teachers' (1) attitudes toward science, (2) science process skills achievement, and (3) sense of science teaching efficacy. Data were collected and analyzed using both quantitative and qualitative methods. Quantitative data were collected using the Science Attitude Inventory (North Carolina Math and Science Education Network (1994), the Test of Integrated Process Skills, TIPS, (Dillashaw & Okey, 1980), and the Science Teaching Efficacy Belief Instrument, STEBI, form B (Enochs & Riggs, 1990). A pretest posttest research design was used for the attitude and process skills constructs. These results were analyzed using paired t test procedures. A pre-experimental group comparison group research design was used for the efficacy construct. Results from this comparison were analyzed using unpaired t test procedures. Qualitative data were collected through students' responses to open-ended questionnaires, narrative interviews, journal entries, small messages, and unsolicited conversations. These data were analyzed via pattern analysis. Posttest scores were significantly higher than pretests scores on both the Science Attitude Inventory and the TIPS. This indicated that students had improved attitudes toward science and science teaching and higher process skills achievement after three semesters in the science-focused PDS program. Scores on the STEBI were significantly higher for students in the pre-experimental group when compared to students in the comparison group. This indicates that students in the science-focused PDS program possessed more efficacious beliefs about science teaching than did the comparison group. Quantitative data were supported by analysis of qualitative data. Implications from this study point to the effectiveness of learning to teach science in a science-focused PDS

Sources of Science Teaching Self-Efficacy for Preservice Elementary Teachers in Science Content Courses

ERIC Educational Resources Information Center

Menon, Deepika; Sadler, Troy D.

2018-01-01

Self-efficacy beliefs play a major role in determining teachers' science teaching practices and have been a topic of great interest in the area of preservice science teacher education. This qualitative study investigated factors that influenced preservice elementary teachers' science teaching self-efficacy beliefs in a physical science content…

Turkish Preservice Elementary Science Teachers' Conceptions of Learning Science and Science Teaching Efficacy Beliefs: Is There a Relationship?

ERIC Educational Resources Information Center

Bahcivan, Eralp; Kapucu, Serkan

2014-01-01

This study has been conducted to investigate conceptions of learning science (COLS) and personal science teaching efficacy belief (PSTE) of Turkish preservice elementary science teachers (PSTs) and to explore the relationship between these variables. Two instruments COLS questionnaire and PSTE subscale of Science Teaching Efficacy Beliefs…

Teaching science for conceptual change: Toward a proposed taxonomy of diagnostic teaching strategies to gauge students' personal science conceptions

NASA Astrophysics Data System (ADS)

Shope, Richard Edwin, III

Science instruction aims to ensure that students properly construct scientific knowledge so that each individual may play a role as a science literate citizen or as part of the science workforce (National Research Council, 1996, 2000). Students enter the classroom with a wide range of personal conceptions regarding science phenomena, often at variance with prevailing scientific views (Duschl, Hamilton, & Grandy, 1992; Hewson, 1992). The extensive misconceptions research literature emphasizes the importance of diagnosing students' initial understandings in order to gauge the accuracy and depth of what each student knows prior to instruction and then to use that information to adapt the teaching to address student needs. (Ausubel, 1968; Carey, 2000; Driver et al., 1985; Karplus & Thier, 1967; Mintzes, Wandersee, & Novak, 1998; Osborne & Freyberg, 1985; Project 2061, 1993; Strike & Posner, 1982, 1992; Vygotsky, 1934/1987). To gain such insight, teachers diagnose not only the content of the students' personal conceptions but also the thinking processes that produced them (Strike and Posner, 1992). Indeed, when teachers design opportunities for students to express their understanding, there is strong evidence that such diagnostic assessment also enhances science teaching and learning (Black & William, 1998). The functional knowledge of effective science teaching practice resides in the professional practitioners at the front lines---the science teachers in the classroom. Nevertheless, how teachers actually engage in the practice of diagnosis is not well documented. To help fill this gap, the researcher conducted a study of 16 sixth grade science classrooms in four Los Angeles area middle schools. Diagnostic teaching strategies were observed in action and then followed up by interviews with each teacher. Results showed that teachers use strategies that vary by the complexity of active student involvement, including pretests, strategic questions, interactive discussion

Students as Mentors and Owners of Geoscience and Environmental Education: Advancing the Science of Climate Change in the Public Schools

NASA Astrophysics Data System (ADS)

Schuster, D. A.; Thomas, C. W.; Smith, J. S.; Wood, E. J.; Filippelli, G. M.

2007-12-01

The importance of K-12 educational programs and resources that seek to share the science of climate change has recently come into focus. During the fall 2006 AGU meeting, we presented the conceptual framework used to guide both the curriculum and year-one programs of Students as Mentors and Owners of Geoscience and Environmental Education: The Global Warming Road Show. Currently this dynamic, three-phase, tiered mentoring program selects and empowers a diverse population of 11th and 12th grade students from a large urban high school in the Midwest to teach a curriculum on climate change to 7th graders from a local feeder school. In December 2007 we will complete year-one of the program and will present an overview of 1) students' conceptual representations of climate change, 2) the most recent curriculum and programs, and 3) the ongoing program evaluation. We will synthesize these three areas and reflect on how to improve upon year-two of both the curriculum and the program. During various stages of the program, students have constructed concept maps, written in journals, created lesson plans, and participated in focus group interviews. These materials are being analyzed to provide a brief overview of high school students' initial conceptualizations of climate change. During the intensive 2007 summer workshop, these 11th and 12th grade students were supported by university scientists and science educators, secondary science teachers, and museum educators as they attempted to better understand climate change and as they reflected on how to effectively teach this topic to 7th graders. During the fall semester of 2007, the workshop graduates are scheduled to teach 25 to 30 7th graders a five week climate unit. The program will culminate with the 11th and 12th grade student-mentors working with the 7th graders to create a "Road Show," which will be presented to other 7th and 8th graders within the same school district. To ensure that this program is current, a team of

In-Service Turkish Elementary and Science Teachers' Attitudes toward Science and Science Teaching: A Sample from Usak Province

ERIC Educational Resources Information Center

Turkmen, Lutfullah

2013-01-01

The purpose of this study is to reveal Turkish elementary teachers' and science teachers' attitudes toward science and science teaching. The sample of the study, 138 in-service elementary level science teachers from a province of Turkey, was selected by a clustered sampling method. The Science Teaching Attitude Scale-II was employed to measure the…

Hidden Treasures for Science Teaching: United States Patents.

ERIC Educational Resources Information Center

Anderson, Norman D.

United States patents are a source of historical information with many implications for science teaching. Using patents as science teaching devices has been largely ignored by science educators. Some of these devices can be easily modified for use in today's classrooms; in addition, patents serve as great examples of how our knowledge of science…

Teacher beliefs about teaching science through Science-Technology-Society (STS)

NASA Astrophysics Data System (ADS)

Massenzio, Lynn

2001-07-01

Statement of the problem. As future citizens, students will have the enormous responsibility of making decisions that will require an understanding of the interaction of science and technology and its interface with society. Since many societal issues today are grounded in science and technology, learning science in its social context is vital to science education reform. Science-Technology-Society (STS) has been strongly identified with meeting this goal, but despite its benefits, putting theory into practice has been difficult. Research design and methodology. The purpose of this study was to explore teacher beliefs about teaching science through STS. The following broad research questions guided the study: (1) What are the participants' initial beliefs about teaching science through STS? (2) What beliefs emerge as participants reflect upon and share their STS instructional experiences with their peers? A social constructivist theoretical framework was developed to plan interactions and collect data. Within this framework, a qualitative methodology was used to interpret the data and answer the research questions. Three provisionally certified science teachers engaged in a series of qualitative tasks including a written essay, verbal STS unit explanation, reflective journal writings, and focus group interviews. After implementing their STS unit, the participants engaged in meaningful dialogue with their peers as they reflected upon, shared, and constructed their beliefs. Conclusions. The participants strongly believed in STS as a means for achieving scientific and technological literacy, developing cognition, enhancing scientific habits of mind and affective qualities, and fostering citizen responsibility. Four major assertions were drawn: (a) Participants' initial belief in teaching for citizen responsibility did not fully align with practice, (b) Educators at the administrative level should be made aware of the benefits of teaching science through STS, (c

Cool Science: Year 2 of Using Children's Artwork about Climate Change to Engage Riders on Mass Transit

NASA Astrophysics Data System (ADS)

Lustick, D. S.; Lohmeier, J.; Chen, R. F.

2014-12-01

A team of educators and scientists from the University of Massachusetts Lowell and the University of Massachusetts Boston will report on the second year of an informal science learning research project using mass transit spaces in Lowell, MA. Cool Science (CS) conducts a statewide art competition for K-12 students in the fall challenging them to express climate science understanding through the visual arts. An inter-disciplinary panel of judges evaluates entries and identifies the top 24 works of art. The best six student works of art are then put on public display throughout the spring on the Lowell Regional Transit Authority (LRTA). Displaying student artwork in Out of Home Multi-Media (OHMM) such as bus placards and posters is intended to engage riders with opportunities to learn informally. CS aims to promote and evaluate learning about climate change science among the general public and k-12 students/teachers. The goals of CS are: 1) Engage teachers, students, and parents in a climate change science communication competition. 2) Display the winning 6 artworks from K-12 students throughout the LRTA. 3) Assess the impact of Cool Science on the teaching and learning of climate science in K-12 formal education. 4) Assess the impact of Cool Science artwork on attitudes, awareness, and understanding of climate change among adult bus riders. A naturalistic inquiry employing a mixed methodology approach best describes our research design. The evaluation focuses on providing feedback regarding the potential learning outcomes for the K-12 students who create the media for the project and the general riding public who engage with the student artwork. To identify possible outcomes, data was collected in the several forms: survey, interviews, and online analytics. We see an urgent need to improve both the public's engagement with climate change science and to the profile of climate change science in formal education settings. The Cool Science (CS) project is an opportunity

Developing Preservice Teachers' Knowledge of Science Teaching Through Video Clubs

NASA Astrophysics Data System (ADS)

Johnson, Heather J.; Cotterman, Michelle E.

2015-06-01

Though an adequate understanding of content is a natural prerequisite of teaching (Carlsen in Journal of Research in Science Teaching 30:471-481, 1993), teachers also need to be able to interpret content in ways that facilitate student learning. How to best support novice teachers in developing and refining their content knowledge for teaching is a crucial and ongoing question for preservice teacher educators. Recently, video clubs are being explored as potential contexts for teacher learning (Barnhart & van Es in Teaching and Teacher Education 45:83-93, 2015; Sherin & Han in Teaching and Teacher Education 20:163-183, 2004). We hypothesized that pairing video clubs with student teaching experiences would provide a forum for preservice teachers to discuss issues relevant to their professional trajectory through exposure to models of peer teaching and opportunities to reflect on practice. In this study, we explored how secondary science preservice teachers used video club to restructure their overall science knowledge into science knowledge for teaching. Our findings suggest that video clubs allowed preservice teachers to access and leverage student thinking and instructional resources to deepen their understanding of science content and trajectories for science learning.

Teaching Science Fiction to Science and Technology Majors.

ERIC Educational Resources Information Center

Diaconoff, Ted

This paper describes the content and implementation of a course designed to teach science and technology majors about science fiction. Although many students had expressed little interest in the imaginative world of literature, the scientific content of the texts used attracted their attention and legitimized their involvement in something outside…

The Northeast Climate Science Center

NASA Astrophysics Data System (ADS)

Ratnaswamy, M. J.; Palmer, R. N.; Morelli, T.; Staudinger, M.; Holland, A. R.

2013-12-01

The Department of Interior Northeast Climate Science Center (NE CSC) is part of a federal network of eight Climate Science Centers created to provide scientific information, tools, and techniques that managers and other parties interested in land, water, wildlife and cultural resources can use to anticipate, monitor, and adapt to climate change. Recognizing the critical threats, unique climate challenges, and expansive and diverse nature of the northeast region, the University of Massachusetts Amherst, College of Menominee Nation, Columbia University, Marine Biological Laboratory, University of Minnesota, University of Missouri Columbia, and University of Wisconsin-Madison have formed a consortium to host the NE CSC. This partnership with the U.S. Geological Survey climate science center network provides wide-reaching expertise, resources, and established professional collaborations in both climate science and natural and cultural resources management. This interdisciplinary approach is needed for successfully meeting the regional needs for climate impact assessment, adaptive management, education, and stakeholder outreach throughout the northeast region. Thus, the NE CSC conducts research, both through its general funds and its annual competitive award process, that responds to the needs of natural resource management partners that exist, in part or whole, within the NE CSC bounds. This domain includes the North Atlantic, Upper Midwest and Great Lakes, Eastern Tallgrass and Big Rivers, and Appalachian Landscape Conservation Cooperatives (LCCs), among other management stakeholders. For example, researchers are developing techniques to monitor tree range dynamics as affected by natural disturbances which can enable adaptation of projected climate impacts; conducting a Designing Sustainable Landscapes project to assess the capability of current and potential future landscapes in the Northeast to provide integral ecosystems and suitable habitat for a suite of

#ClimateEdCommunity : Field Workshops Bring Together Teachers and Researchers to Make Meaning of Science and Classroom Integration

NASA Astrophysics Data System (ADS)

Bartholow, S.; Warburton, J.; Wood, J. H.; Steiner, S. M.

2015-12-01

Seeing Understanding and Teaching: Climate Change in Denali is a four-day immersive teacher professional development course held in Denali National Park. Developed through three partner organizations, the course aims to develop teachers' skills for integrating climate change content into their classrooms. This presentation aims to share tangible best practices for linking researchers and teachers in the field, through four years of experience in program delivery and reported through a published external evaluation. This presentation will examine the key aspects of a successful connection between teachers, researchers, science, and classrooms: (1) Inclusion of teacher leaders, (2) dedicated program staff, (3) workshop community culture, and will expose barriers to this type of collaboration including (1) differences in learning style, (2) prior teaching experience, (3) existing/scaffolding understanding of climate change science, and (4) accessibility of enrollment and accommodations for the extended learning experience. Presentation Content Examples:Participants overwhelmingly value the deep commitment this course has to linking their field experience to the classroom attributing to the role of a teacher-leader; an expert science teacher with first-hand field research experience in the polar regions. The goal of including a teacher-leader is to enhance translatability between fieldwork and the classroom. Additionally, qualitative aspects of the report touches on the intangible successes of the workshop such as: (1) the creation of a non-judgmental learning atmosphere, (2) addressing accessibility to science learning tools in rural and under-served communities, (3) defining successful collaboration as making meaning together through exploratory questioning while in the field (4) discussed the social and cultural implications of climate change, and the difficulty of navigating these topics in educational and/or multicultural spaces. Next Steps? Create a #Climate

Pre-Service Science Teachers' Epistemological Beliefs and Teaching Reforms in Tanzania

ERIC Educational Resources Information Center

Tarmo, Albert

2016-01-01

In an effort to understand why recent initiatives to promote learner-centred pedagogy in science teaching made a little change in the actual teaching practices of science teachers, this study explored pre-service science teachers' beliefs about science knowledge and their teaching practices. Six pre-service science teachers were interviewed to…

Regional climate science: lessons and opportunities

NASA Astrophysics Data System (ADS)

Mote, P. W.; Miles, E. L.; Whitely Binder, L.

2008-12-01

Since its founding in 1995, the Climate Impacts Group (CIG) at the University of Washington (UW) has achieved remarkable success at translating global- and regional-scale science into forms and products that are useful to, and used by, decision-makers. From GCM scenarios to research on the connection between global climate patterns and locally important factors like floods and wildfires, CIG's strong physical science foundation is matched by a vigorous and successful outreach program. As a result, CIG and its partner the Office of Washington State Climatologist at UW have made substantial progress at bridging the gap between climate science and decision-making, and are deeply involved in advising all levels of government and many business interests on adapting to climate variability and change. This talk will showcase some of the specific activities and tools, describe lessons learned, and illustrate how such efforts fit into a "National Climate Service."

Communicating Climate Science to Kids and Adults Through Citizen Science, Hands-On Demonstrations, and a Personal Approach

NASA Astrophysics Data System (ADS)

Cherry, L.; Braasch, G.

2008-12-01

There is a demonstrated need to increase the amount of formal and non-formal science education and to raise the level of climate literacy for children and adults. Scientists and technical leaders are more and more being called on to speak in non-academic settings ranging from grade schools to assemblies and seminars for the general public. This abstract describes some effective ways to teach and talk about climate change science in a way that engenders hope and empowerment while explaining scientific facts and research methods to non-scientists. Citizen participation in Science People's interest and learning increases when offered chances to do what scientists do. Relating science to their daily lives and showing the adventure of science can greatly increase communication. Citizen participation in science works because data collection stimulates experiential and cognitive ways of learning. Learn what programs for citizen science are available in your area. For instance, GLOBE and Budburst tie into the research of Smithsonian scientists who determined that the cherry blossoms and 40 other species of plants were blooming earlier due to climate warming. Hands-on Outdoor Activities Information enters the human brain through many different neural pathways and the more avenues that information comes in on, the more likely people are to retain that knowledge for their lifetimes. For instance, kids knowledge of how ice cores tell us about the earth's ancient history will be reinforced through making ice cores in the classroom. Gary Braasch's photographs from the children's book How We Know What We Know About Our Changing Climate: Scientists and Kids Explore Global Warming and from his adult book Earth Under Fire: How Global Warming is Changing the World will illustrate the presentation. . Making the Message Personal to the Audience. Reaching people through things they care about, their family lives, work or school and telling personal stories helps reach people. The videos

Climate Literacy and Energy Awareness Network (CLEAN) - Supporting the Scientists and Citizens of Tomorrow

NASA Astrophysics Data System (ADS)

Ledley, T. S.; McCaffrey, M. S.; Gold, A. U.; Buhr, S. M.; Manduca, C. A.; Fox, S.; Kirk, K. B.; Grogan, M.; Niepold, F.; Lynds, S. E.; Howell, C.

2011-12-01

The US Global Change Research Program and a consortium of science and education partners in 2009 concluded "climate change will bring economic and environmental challenges as well as opportunities, and citizens who have an understanding of climate science will be better prepared to respond to both." In order for citizens to achieve that understanding there is a clear need to support teachers, students, and the public in becoming climate and energy literate and to enable them to make responsible decisions about the environment and energy use for themselves and for society. However, to pursue climate and energy literacy it is necessary to identify and access educational materials that are scientifically accurate, pedagogically effective, and technically robust, and to use them effectively. The CLEAN Pathway (http://cleanet.org) is a National Science Digital Library (http://www.nsdl.org) project that is stewarding a collection of materials for teaching climate and energy science in grades 6-16. The collection contains classroom activities, lab demonstrations, visualizations, simulations and more. Each resource is extensively reviewed for scientific accuracy, pedagogical effectiveness, and technical quality. Once accepted into the CLEAN collection, a resource is aligned with the Climate Literacy Essential Principles for Climate Science, the AAAS Project 2061 Benchmarks for Science Literacy and other national standards. The CLEAN website hosts a growing collection of currently 300+ resources that represent the leading edge of climate and energy science resources for the classroom. In this presentation we will demonstrate the various avenues of how the CLEAN portal that can help educators improve their own climate and energy literacy, help them determine why and how to effectively integrate the climate and energy principles into their teaching, and facilitate educators successfully using the resources with their students. This will include a brief overview of the: a

Teaching Climate Change to Future Teachers Using 'Real' Data: Challenges and Opportunities (Invited)

NASA Astrophysics Data System (ADS)

Petcovic, H. L.; Barone, S.; Fulford, J.

2013-12-01

A climate-literate public is essential to resolving pressing problems related to global change. Future elementary teachers are a critical audience in climate and climate change education, as they will introduce children in early grades (USA grades K-8, children ages 5-14) to fundamentals of the climate system, natural and anthropogenic drivers of climate change, and impacts of global change on human and natural systems. Here we describe challenges we have encountered in teaching topics of the carbon cycle, greenhouse gases, past climate, recent anthropogenic change, and carbon footprints to future elementary teachers. We also describe how we have met (to varying degrees of success) these challenges in an introductory earth science course that is specifically designed for this audience. Two prominent challenges we have encountered are: the complex nature of the scientific content of climate change, and robust misconceptions held by our students about these topics. To address the first challenge, we attempt to adjust the scientific content to a level appropriate for future K-8 teachers, without sacrificing too much accuracy or critical detail. To address the second challenge, we explicitly discuss alternate conceptions of each topic. The use of authentic data sets can also address both of these challenges. Yet incorporating 'real' climate and paleoclimate data into the classroom poses still an additional challenge of instructional design. We use a variety of teaching approaches in our laboratory-based course including student-designed experiments, computer simulations, physical models, and authentic data sets. We have found that students strongly prefer the physical models and experiments, because these are 'hands-on' and perceived as easily adaptable to the K-8 classroom. Students often express dislike for activities that use authentic data sets (for example, an activity using graphs of CO2 and methane concentrations in Vostok ice cores), in particular because they

Impact of SCALE-UP on science teaching self-efficacy of students in general education science courses

NASA Astrophysics Data System (ADS)

Cassani, Mary Kay Kuhr

The objective of this study was to evaluate the effect of two pedagogical models used in general education science on non-majors' science teaching self-efficacy. Science teaching self-efficacy can be influenced by inquiry and cooperative learning, through cognitive mechanisms described by Bandura (1997). The Student Centered Activities for Large Enrollment Undergraduate Programs (SCALE-UP) model of inquiry and cooperative learning incorporates cooperative learning and inquiry-guided learning in large enrollment combined lecture-laboratory classes (Oliver-Hoyo & Beichner, 2004). SCALE-UP was adopted by a small but rapidly growing public university in the southeastern United States in three undergraduate, general education science courses for non-science majors in the Fall 2006 and Spring 2007 semesters. Students in these courses were compared with students in three other general education science courses for non-science majors taught with the standard teaching model at the host university. The standard model combines lecture and laboratory in the same course, with smaller enrollments and utilizes cooperative learning. Science teaching self-efficacy was measured using the Science Teaching Efficacy Belief Instrument - B (STEBI-B; Bleicher, 2004). A science teaching self-efficacy score was computed from the Personal Science Teaching Efficacy (PTSE) factor of the instrument. Using non-parametric statistics, no significant difference was found between teaching models, between genders, within models, among instructors, or among courses. The number of previous science courses was significantly correlated with PTSE score. Student responses to open-ended questions indicated that students felt the larger enrollment in the SCALE-UP room reduced individual teacher attention but that the large round SCALE-UP tables promoted group interaction. Students responded positively to cooperative and hands-on activities, and would encourage inclusion of more such activities in all of the

Recruiting Science Majors into Secondary Science Teaching: Paid Internships in Informal Science Settings

ERIC Educational Resources Information Center

Worsham, Heather M.; Friedrichsen, Patricia; Soucie, Marilyn; Barnett, Ellen; Akiba, Motoko

2014-01-01

Despite the importance of recruiting highly qualified individuals into the science teaching profession, little is known about the effectiveness of particular recruitment strategies. Over 3 years, 34 college science majors and undecided students were recruited into paid internships in informal science settings to consider secondary science teaching…

Our Changing Climate

ERIC Educational Resources Information Center

Newhouse, Kay Berglund

2007-01-01

In this article, the author discusses how global warming makes the leap from the headlines to the classroom with thought-provoking science experiments. To teach her fifth-grade students about climate change, the author starts with a discussion of the United States' local climate. They extend this idea to contrast the local climate with others,…

Teaching Efficacy of Universiti Putra Malaysia Science Student Teachers

ERIC Educational Resources Information Center

Bakar, Abd. Rahim; Konting, Mohd. Majid; Jamian, Rashid; Lyndon, Novel

2008-01-01

The objective of the study was to access teaching efficacy of Universiti Putra Malaysia Science student teachers. The specific objectives were to determine teaching efficacy of Science student teachers in terms of student engagement; instructional strategies; classroom management and teaching with computers in classroom; their satisfaction with…

Early childhood teachers' self-efficacy toward teaching science: Outcomes of professional development

NASA Astrophysics Data System (ADS)

Clark, Sarah

The teaching of science in the early childhood classrooms has slowly been decreasing. As the years have passed, the subject of science has been put on the backburner while mathematics and language arts have taken center stage in the educational system. Early childhood teachers need to find ways to integrate science with other subjects in order to ensure children are receiving a well-rounded and full education. The purpose of this study was to determine the effectiveness of professional development on teachers' efficacy in teaching science. Volunteer teachers completed the Weisgram and Bigler scale (TWBS) pre and post training, in order to determine their self-efficacy toward teaching science, they also completed pre- and post- concept maps about their knowledge of teaching science, and a demographic questionnaire. Findings indicate the training provided was effective in increasing teachers' knowledge of teaching science. Teachers who had an increase in science teaching knowledge were also found to feel more efficacious about teaching science after completing the training and an academic year of implementing science lessons in their classrooms. There was not a relationship between teacher demographics and their science-teaching efficacy. This means that the demographics of participants in this study were not influential on teachers' efficacy, but professional development workshops enabled teachers to gain more knowledge about teaching as well as increase their efficacy about teaching science.

Teaching the process of science: faculty perceptions and an effective methodology.

PubMed

Coil, David; Wenderoth, Mary Pat; Cunningham, Matthew; Dirks, Clarissa

2010-01-01

Most scientific endeavors require science process skills such as data interpretation, problem solving, experimental design, scientific writing, oral communication, collaborative work, and critical analysis of primary literature. These are the fundamental skills upon which the conceptual framework of scientific expertise is built. Unfortunately, most college science departments lack a formalized curriculum for teaching undergraduates science process skills. However, evidence strongly suggests that explicitly teaching undergraduates skills early in their education may enhance their understanding of science content. Our research reveals that faculty overwhelming support teaching undergraduates science process skills but typically do not spend enough time teaching skills due to the perceived need to cover content. To encourage faculty to address this issue, we provide our pedagogical philosophies, methods, and materials for teaching science process skills to freshman pursuing life science majors. We build upon previous work, showing student learning gains in both reading primary literature and scientific writing, and share student perspectives about a course where teaching the process of science, not content, was the focus. We recommend a wider implementation of courses that teach undergraduates science process skills early in their studies with the goals of improving student success and retention in the sciences and enhancing general science literacy.

Teaching the Process of Science: Faculty Perceptions and an Effective Methodology

PubMed Central

Coil, David; Wenderoth, Mary Pat; Cunningham, Matthew

2010-01-01

Most scientific endeavors require science process skills such as data interpretation, problem solving, experimental design, scientific writing, oral communication, collaborative work, and critical analysis of primary literature. These are the fundamental skills upon which the conceptual framework of scientific expertise is built. Unfortunately, most college science departments lack a formalized curriculum for teaching undergraduates science process skills. However, evidence strongly suggests that explicitly teaching undergraduates skills early in their education may enhance their understanding of science content. Our research reveals that faculty overwhelming support teaching undergraduates science process skills but typically do not spend enough time teaching skills due to the perceived need to cover content. To encourage faculty to address this issue, we provide our pedagogical philosophies, methods, and materials for teaching science process skills to freshman pursuing life science majors. We build upon previous work, showing student learning gains in both reading primary literature and scientific writing, and share student perspectives about a course where teaching the process of science, not content, was the focus. We recommend a wider implementation of courses that teach undergraduates science process skills early in their studies with the goals of improving student success and retention in the sciences and enhancing general science literacy. PMID:21123699

Department of the Interior Climate Science Centers

USGS Publications Warehouse

Jones, Sonya A.

2011-01-01

What is a Climate Science Center? On September 14, 2009, the Secretary of the Interior signed a Secretarial Order (No. 3289) entitled, "Addressing the Impacts of Climate Change on America's Water, Land, and Other Natural and Cultural Resources." The Order effectively established the U.S. Department of the Interior (DOI) Climate Science Centers (CSCs), which will integrate DOI science and management expertise with similar contributions from our partners to provide information to support adaptation and mitigation efforts on both public and private lands, across the United States and internationally.The Southeast CSC, hosted by NC State University (NCSU), will collaborate with a number of other universities, State and Federal agencies, and nongovernmental organizations (NGOs) with interest and expertise in climate science. The primary partner for the Southeast CSC will be the Landscape Conservation Cooperatives (LCCs) in the Southeast, including the Appalachian, Gulf Coastal Plains and Ozarks, Gulf Coast Prairie, Peninsular Florida, and the South Atlantic. CSC collaborations are focused on common science priorities, addressing priority partner needs, minimizing redundancies in science, sharing scientific findings, and expanding understanding of climate change impacts in the Southeast.

Building the Capacity for Climate Services: Thoughts on Training Next Generation Climate Science Integrators

NASA Astrophysics Data System (ADS)

Garfin, G. M.; Brugger, J.; Gordon, E. S.; Barsugli, J. J.; Rangwala, I.; Travis, W.

2015-12-01

For more than a decade, stakeholder needs assessments and reports, including the recent National Climate Assessment, have pointed out the need for climate "science translators" or "science integrators" who can help bridge the gap between the cultures and contexts of researchers and decision-makers. Integration is important for exchanging and enhancing knowledge, building capacity to use climate information in decision making, and fostering more robust planning for decision-making in the context of climate change. This talk will report on the characteristics of successful climate science integrators, and a variety of models for training the upcoming generation of climate science integrators. Science integration characteristics identified by an experienced vanguard in the U.S. include maintaining credibility in both the scientific and stakeholder communities, a basic respect for stakeholders demonstrated through active listening, and a deep understanding of the decision-making context. Drawing upon the lessons of training programs for Cooperative Extension, public health professionals, and natural resource managers, we offer ideas about training next generation climate science integrators. Our model combines training and development of skills in interpersonal relations, communication of science, project implementation, education techniques and practices - integrated with a strong foundation in disciplinary knowledge.

Climate Science's Globally Distributed Infrastructure

NASA Astrophysics Data System (ADS)

Williams, D. N.

2016-12-01

The Earth System Grid Federation (ESGF) is primarily funded by the Department of Energy's (DOE's) Office of Science (the Office of Biological and Environmental Research [BER] Climate Data Informatics Program and the Office of Advanced Scientific Computing Research Next Generation Network for Science Program), the National Oceanic and Atmospheric Administration (NOAA), the National Aeronautics and Space Administration (NASA), and the National Science Foundation (NSF), the European Infrastructure for the European Network for Earth System Modeling (IS-ENES), and the Australian National University (ANU). Support also comes from other U.S. federal and international agencies. The federation works across multiple worldwide data centers and spans seven international network organizations to provide users with the ability to access, analyze, and visualize data using a globally federated collection of networks, computers, and software. Its architecture employs a series of geographically distributed peer nodes that are independently administered and united by common federation protocols and application programming interfaces (APIs). The full ESGF infrastructure has now been adopted by multiple Earth science projects and allows access to petabytes of geophysical data, including the Coupled Model Intercomparison Project (CMIP; output used by the Intergovernmental Panel on Climate Change assessment reports), multiple model intercomparison projects (MIPs; endorsed by the World Climate Research Programme [WCRP]), and the Accelerated Climate Modeling for Energy (ACME; ESGF is included in the overarching ACME workflow process to store model output). ESGF is a successful example of integration of disparate open-source technologies into a cohesive functional system that serves the needs the global climate science community. Data served by ESGF includes not only model output but also observational data from satellites and instruments, reanalysis, and generated images.

An Examination of Climate Scientists' Participation in Education: Implications for Supporting the Teaching and Learning of Socially Controversial Science

ERIC Educational Resources Information Center

Walsh, Elizabeth M.

2012-01-01

Preparing a generation of citizens to respond to the impacts of climate change will require collaborative interactions between natural scientists, learning scientists, educators and learners. Promoting effective involvement of scientists in climate change education is especially important as climate change science and climate impacts are…

Toward making the invisible visible: Studying science teaching self-efficacy beliefs

NASA Astrophysics Data System (ADS)

Perkins, Catherine J.

This dissertation consists of two articles to be submitted for publication. The first, a literature review, makes visible common influences on science teaching self-efficacy beliefs and also points to potentially invisible validation concerns regarding the instrument used. The second investigates the participants' invisible science teaching self-efficacy beliefs and, through the use of a more focused interview, makes those beliefs visible. Science teaching self-efficacy beliefs are science teachers' perceptions of their abilities to teach science effectively. The construct "teaching self-efficacy" originated in social cognitive theory (Bandura, 1977). The first article reviews the mixed results from teaching self-efficacy research in science contexts. The review focuses upon factors that facilitate or inhibit the development of self-efficacy beliefs among science teachers across stages of their careers. Although many studies of science teaching self-efficacy beliefs have utilized the Science Teaching Efficacy Belief Instrument - STEBI (Enochs & Riggs, 1990; Riggs & Enochs, 1990), this review also includes non-STEBI studies in order to represent diverse lines of research methodology. The review's findings indicate that antecedent factors such as science activities in and out of school, teacher preparation, science teaching experiences and supportive job contexts are significant influences on the development of science teaching self-efficacy beliefs. The review also indicates that the majority of these studies are short term and rely on a single STEBI administration with the collection of antecedent/demographic and/or interview data. The second article documents a study that responded to the above literature review findings. This study utilized multiple STEBI administrations during the preservice and beginning year of teaching for two science teachers. Rather than general questions, these participants were asked item specific, yet open-ended, questions to determine

Caught in the Balance: An Organizational Analysis of Science Teaching in Schools with Elementary Science Specialists

ERIC Educational Resources Information Center

Marco-Bujosa, Lisa M.; Levy, Abigail Jurist

2016-01-01

Elementary schools are under increasing pressure to teach science and teach it well; yet, research documents that classroom teachers must overcome numerous personal and school-based challenges to teach science effectively at this level, such as access to materials and inadequate instructional time. The elementary science specialist model…

The ontology of science teaching in the neoliberal era

NASA Astrophysics Data System (ADS)

Sharma, Ajay

2017-12-01

Because of ever stricter standards of accountability, science teachers are under an increasing and unrelenting pressure to demonstrate the effects of their teaching on student learning. Econometric perspectives of teacher quality have become normative in assessment of teachers' work for accountability purposes. These perspectives seek to normalize some key ontological assumptions about teachers and teaching, and thus play an important role in shaping our understanding of the work science teachers do as teachers in their classrooms. In this conceptual paper I examine the ontology of science teaching as embedded in econometric perspectives of teacher quality. Based on Foucault's articulation of neoliberalism as a discourse of governmentality in his `The Birth of Biopolitics' lectures, I suggest that this ontology corresponds well with the strong and substantivist ontology of work under neoliberalism, and thus could potentially be seen as reflection of the influence of neoliberal ideas in education. Implications of the mainstreaming of an ontology of teaching that is compatible with neoliberalism can be seen in increasing marketization of teaching, `teaching evangelism', and impoverished notions of learning and teaching. A shift of focus from teacher quality to quality of teaching and building conceptual models of teaching based on relational ontologies deserve to be explored as important steps in preserving critical and socially just conceptions of science teaching in neoliberal times.

Tackling Weather and Climate Change Creatively in Science

ERIC Educational Resources Information Center

Dale, Murray

2013-01-01

In this article, the author offers some practical support for teaching about weather, climate and climate change. In England, weather and climate are traditionally taught within the geography curriculum, although it is actually a very scientific subject, involving skills such as making careful observations and measurements, interpreting data…

The Pacific Northwest's Climate Impacts Group: Climate Science in the Public Interest

NASA Astrophysics Data System (ADS)

Mantua, N.; Snover, A.

2006-12-01

Since its inception in 1995, the University of Washington's Climate Impacts Group (CIG) (funded under NOAA's Regional Integrated Science and Assessments (RISA) Program) has become the leader in exploring the impacts of climate variability and climate change on natural and human systems in the U.S. Pacific Northwest (PNW), specifically climate impacts on water, forest, fish and coastal resource systems. The CIG's research provides PNW planners, decision makers, resource managers, local media, and the general public with valuable knowledge of ways in which the region's key natural resources are vulnerable to changes in climate, and how this vulnerability can be reduced. The CIG engages in climate science in the public interest, conducting original research on the causes and consequences of climate variability and change for the PNW and developing forecasts and decision support tools to support the use of this information in federal, state, local, tribal, and private sector resource management decisions. The CIG's focus on the intersection of climate science and public policy has placed the CIG nationally at the forefront of regional climate impacts assessment and integrated analysis.

Climate state: Science-state struggles and the formation of climate science in the US from the 1930s to 1960s.

PubMed

Baker, Zeke

2017-12-01

This article has two aims: first, to understand the co-production of climate science and the state, and second, to provide a test case for Pierre Bourdieu's field theory. To these ends, the article reconstructs the historical formation of a US climate science field, with an analytic focus on inter-field dynamics and heterogeneous networking practices. Drawing from primary- and secondary-source materials, the historical analysis focuses on relations between scientists and state actors from the 1930s to the 1960s. The account shows how actors with positions linking scientific and bureaucratic fields constructed critical nodes and 'hinges' that co-produced war-making and state expansion on the one hand, and a relatively autonomous climate science field on the other. The analysis explains the emergence of climate science by focusing on the WWII-era transformation of meteorology and oceanography into distinct disciplines, the emergence of 'basic' research as a central principle of post-war government, and the formation of a climate science field by the 1960s centered on computerized modeling and populated by an interdisciplinary scientific elite. The article concludes by indicating how these processes led to the subsequent development of climate change as a science-state conundrum that has reorganized the climate science field in recent decades.

Climate Science Program at California State University, Northridge

NASA Astrophysics Data System (ADS)

Steele Cox, H.; Klein, D.; Cadavid, A. C.; Foley, B.

2012-12-01

Due to its interdisciplinary nature, climate science poses wide-ranging challenges for science and mathematics students seeking careers in this field. There is a compelling need for universities to provide coherent programs in climate science in order to train future climate scientists. With funding from NASA Innovations in Climate Education (NICE), California State University, Northridge (CSUN), is creating the CSUN Climate Science Program. An interdisciplinary team of faculty members is working in collaboration with UCLA, Santa Monica College and NASA/JPL partners to create a new curriculum in climate science. The resulting sequence of climate science courses, or Pathway for studying the Mathematics of Climate Change (PMCC), is integrated into a Bachelor of Science degree program in the Applied Mathematical Sciences offered by the Mathematics Department at CSUN. The PMCC consists of courses offered by the departments of Mathematics, Physics, and Geography and is designed to prepare students for Ph.D. programs in technical fields relevant to global climate change and related careers. The students who choose to follow this program will be guided to enroll in the following sequence of courses for their 12 units of upper division electives: 1) A newly created course junior level course, Math 396CL, in applied mathematics which will introduce students to applications of vector calculus and differential equations to the study of thermodynamics and atmospheric dynamics. 2) An already existing course, Math 483, with new content on mathematical modeling specialized for this program; 3) An improved version of Phys 595CL on the mathematics and physics of climate change with emphasis on Radiative Transfer; 4) A choice of Geog 407 on Remote Sensing or Geog 416 on Climate Change with updated content to train the students in the analysis of satellite data obtained with the NASA Earth Observing System and instruction in the analysis of data obtained within a Geographical

Teaching and learning: Novice teachers' descriptions of their confidence to teach science content

NASA Astrophysics Data System (ADS)

Ford, Barbara Ann

Statement of the problem. The problem being studied in this research is the relationship between a specific series of integrated science courses in a science teacher preparation program and the actual needs of the science teacher during the first years of teaching practice. Teachers often report that there is a disconnect between the coursework they have taken in college as pre-service teachers and the reality of their classroom practice during their first years of teaching. The intent of this study was to record the descriptions of three teachers who were members of a cohort and took a series of integrated science courses (NSCI series) during their teacher preparation program as it related to the influence of these courses on their teaching practice. The focus of inquiry is guided by a single question: How do former participants in the series of science courses who are currently novice teachers describe their confidence in their ability to teach science content to their middle school students? The theoretical framework was based on Shulman's (1987) pedagogical content knowledge (PCK). PCK involves the teacher understanding the content of science so thoroughly that ways are identified of representing and formulating the subject matter to make it understandable to others. The teacher who has a strong PCK uses powerful analogies, illustrations, examples, explanations and demonstrations that promote personally meaningful student understandings. Novice teachers' reflections on their confidence to teach science content to their middle school students were observed through the lens of PCK. All three novice teachers reported a high confidence level to teach middle school science and attributed their confidence level to a great degree to the integrated science series of courses (NSCI). Method. A qualitative design, specifically a case study, was used for this study. Multiple forms of data collection were employed including a semi structured interview and a focus group

The National Climate Assessment as a Resource for Science Communication

NASA Astrophysics Data System (ADS)

Somerville, R. C. J.

2014-12-01

The 2014 Third National Climate Assessment (NCA3) is scientifically authoritative and features major advances, relative to other assessments produced by several organizations. NCA3 is a valuable resource for communicating climate science to a wide variety of audiences. Other assessments were often overly detailed and laden with scientific jargon that made them appear too complex and technical to many in their intended audiences, especially policymakers, the media, and the broad public. Some other assessments emphasized extensive scientific caveats, quantitative uncertainty estimates and broad consensus support. All these attributes, while valuable in research, carry the risk of impeding science communication to non-specialists. Without compromising scientific accuracy and integrity, NCA3 is written in exceptionally clear and vivid English. It includes outstanding graphics and employs powerful techniques aimed at conveying key results unambiguously to a wide range of audiences. I have used NCA3 as a resource in speaking about climate change in three very different settings: classroom teaching for undergraduate university students, presenting in academia to historians and other non-scientists, and briefing corporate executives working on renewable energy. NCA3 proved the value of developing a climate assessment with communication goals and strategies given a high priority throughout the process, not added on as an afterthought. I draw several lessons. First, producing an outstanding scientific assessment is too complex and demanding a task to be carried out by scientists alone. Many types of specialized expertise are also needed. Second, speaking about science to a variety of audiences requires an assortment of communication skills and tools, all tailored to specific groups of listeners. Third, NCA3 is scientifically impeccable and is also an outstanding example of effective communication as well as a valuable resource for communicators.

Recent Challenges Facing US Government Climate Science Access and Application

NASA Astrophysics Data System (ADS)

Goldman, G. T.; Carter, J. M.; Licker, R.

2017-12-01

Climate scientists have long faced politicization of their work, especially those working within the US federal government. However, political interference in federal government climate change science has escalated in the current political era with efforts by political actors to undermine and disrupt infrastructure supporting climate science. This has included funding changes, decreased access to climate science information on federal agency websites, restrictions on media access to scientific experts within the government, and rolling back of science-based policies designed to incorporate and respond to climate science findings. What are the impacts of such changes for both the climate science community and the broader public? What can be done to ensure that access to and application of climate change-related research to policy decisions continues? We will summarize and analyze the state of climate change research and application in the US government. The impacts of political interference in climate change science as well as opportunities the scientific community has to support climate science in the US government, will be discussed.

Engaging Students In The Science Of Climate Change

NASA Astrophysics Data System (ADS)

Rhew, R. C.; Halversen, C.; Weiss, E.; Pedemonte, S.; Weirman, T.

2013-12-01

Climate change is arguably the defining environmental issue of our generation. It is thus increasingly necessary for every member of the global community to understand the basic underlying science of Earth's climate system and how it is changing in order to make informed, evidence-based decisions about how we will respond individually and as a society. Through exploration of the inextricable interconnection between Earth's ocean, atmosphere and climate, we believe students will be better prepared to tackle the complex issues surrounding the causes and effects of climate change and evaluate possible solutions. If students are also given opportunities to gather evidence from real data and use scientific argumentation to make evidence-based explanations about climate change, not only will they gain an increased understanding of the science concepts and science practices, the students will better comprehend the nature of climate change science. Engaging in argument from evidence is a scientific practice not only emphasized in the Framework for K-12 Science Education and the Next Generation Science Standards (NGSS), but also emphasized in the Common Core State Standards for English Language Arts & Literacy in History/Social Studies and Science (CCSS). This significant overlap between NGSS and CCSS has implications for science and language arts classrooms, and should influence how we support and build students' expertise with this practice of sciences. The featured exemplary curricula supports middle school educators as they address climate change in their classrooms. The exemplar we will use is the NOAA-funded Ocean Sciences Sequence (OSS) for Grades 6-8: The ocean-atmosphere connection and climate change, which are curriculum units that deliver rich science content correlated to the Next Generation Science Standards (NGSS) Disciplinary Core Ideas and an emphasis on the Practices of Science, as called for in NGSS and the Framework. Designed in accordance with the latest

Secondary Physical Science Teachers' Conceptions of Science Teaching in a Context of Change

NASA Astrophysics Data System (ADS)

Taylor, Dale L.; Booth, Shirley

2015-05-01

Pre-service teachers enter initial teacher education programmes with conceptions of teaching gleaned from their own schooling. These conceptions, which include teachers' beliefs, may be resistant to change, which is a challenge in contexts where teacher educators hope that teachers will teach in ways different from their own schooling. Conceptions of teaching found in different cultural and disciplinary contexts have contextual differences but have resonances with the results of research into teacher beliefs. Our sample of eight South African secondary physical science teachers was schooled in a system which encouraged knowledge transmission, but they were prepared in their initial teacher education for a learner-centred approach. After they had taught for a few years, we explored their conceptions of science teaching, using phenomenographic interviews. Four conceptions emerged inductively from the analysis: transferring science knowledge from mind to mind; transferring problematic science knowledge from mind to mind; creating space for learning science knowledge and creating space for learning problematic science knowledge. Internally these conceptions are constituted by three dimensions of variation: the nature of the science knowledge to be learnt, the role of the students and the role of the teacher. Media and practical work play different roles in the external horizon of these conceptions. These conceptions reflect the disciplinary context as well as the emphases of the sample's initial teacher education programme. This suggests that initial teacher education can significantly shape teachers' conceptions of teaching.

Climate Science across the Liberal Arts Curriculum at Gustavus Adolphus College

NASA Astrophysics Data System (ADS)

Bartley, J. K.; Triplett, L.; Dontje, J.; Huber, T.; Koomen, M.; Jeremiason, J.; La Frenierre, J.; Niederriter, C.; Versluis, A.

2014-12-01

The human and social dimensions of climate change are addressed in courses in humanities, social sciences, and arts disciplines. However, faculty members in these disciplines are not climate science experts and thus may feel uncomfortable discussing the science that underpins our understanding of climate change. In addition, many students are interested in the connections between climate change and their program of study, but not all students take courses that address climate science as a principal goal. At Gustavus Adolphus College, the Climate Science Project aims to help non-geoscience faculty introduce climate science content in their courses in order to increase climate science literacy among students and inform discussions of the implications of climate change. We assembled an interdisciplinary team of faculty with climate science expertise to develop climate science modules for use in non-geoscience courses. Faculty from the social sciences, humanities, arts, education, and natural sciences attended workshops in which they developed plans to include climate science in their courses. Based on these workshops, members of the development team created short modules for use by participating faculty that introduce climate science concepts to a non-specialist audience. Each module was tested and modified prior to classroom implementation by a team of faculty and geoscience students. Faculty and student learning are assessed throughout the process, and participating faculty members are interviewed to improve the module development process. The Climate Science Project at Gustavus Adolphus College aims to increase climate science literacy in both faculty members and students by creating accessible climate science content and supporting non-specialist faculty in learning key climate science concepts. In this way, climate science becomes embedded in current course offerings, including non-science courses, reaching many more students than new courses or enhanced content

Cool Science: Engaging Adult and K-16 Audiences in Climate Change Science

NASA Astrophysics Data System (ADS)

Lustick, D.; Lohmeier, J.; Chen, R. F.

2012-12-01

A team of educators and scientists from the University of Massachusetts Lowell and the University of Massachusetts Boston will report on an informal science learning research project using mass transit spaces in Lowell, MA. Cool Science (CS) uses advertising spaces on buses and terminals to engage the public with an Out of Home Multi-Media (OHMM) learning experience. K-16 classrooms throughout Massachusetts will submit original artwork that conveys a scientific concept central to understanding climate change. The best 6 works submitted will be printed and placed on every bus in the city over a 6 month period during the first half of 2013. CS aims to promote and evaluate learning about climate change science among the general adult public and k-16 students/teachers. Cool Science offers teachers an efficient and effective means of seamlessly bringing the study of climate change into classroom learning both within science and across disciplines. The products of this effort are then used to improve public engagement with the science of climate change in mass transit environments. Cool Science is an example of Science, Technology, Engineering, Art and Math education (STEAM). The goals of CS are: 1) Engage professors, teachers, and their respective students in a climate change science communication competition. 2) Run the winning 6 selected placards and posters throughout the LRTA. 3) Identify how different communities of risk among the riding public approach and understand climate change. 4) Identify the advantages and disadvantages of using buses as a context for research on informal science learning. 5) Determine the extent to which student artwork serves as a trusted source of information. As advances in technology allow for more scientific knowledge to be generated, the role of informal education to improve adult understanding of science has never been greater. We see the convergence of circumstances (ISE, climate change, OHMM, mobile technology) as an enormous

Jordanian Preservice Primary Teachers' Perceptions of Mentoring in Science Teaching

NASA Astrophysics Data System (ADS)

Abed, Osama H.; Abd-El-Khalick, Fouad

2015-03-01

Quality mentoring is fundamental to preservice teacher education because of its potential to help student and novice teachers develop the academic and pedagogical knowledge and skills germane to successful induction into the profession. This study focused on Jordanian preservice primary teachers' perceptions of their mentoring experiences as these pertain to science teaching. The Mentoring for Effective Primary Science Teaching instrument was administered to 147 senior preservice primary teachers in a university in Jordan. The results indicated that the greater majority of participants did not experience effective mentoring toward creating a supportive and reflexive environment that would bolster their confidence in teaching science; further their understanding of primary science curriculum, and associated aims and school policies; help with developing their pedagogical knowledge; and/or furnish them with specific and targeted feedback and guidance to help improve their science teaching. Substantially more participants indicated that their mentors modeled what they perceived to be effective science teaching. The study argues for the need for science-specific mentoring for preservice primary teachers, and suggests a possible pathway for achieving such a model starting with those in-service primary teachers-much like those identified by participants in the present study-who are already effective in their science teaching.

Teaching science as inquiry in US and in Japan: A cross-cultural comparison of science teachers' understanding of, and attitudes toward inquiry-based teaching

NASA Astrophysics Data System (ADS)

Tosa, Sachiko

Since the publication of the National Science Education Standards in 1996, learning science through inquiry has been regarded as the heart of science education. However, the TIMSS 1999 Video Study showed that inquiry-based teaching has been taking place less in the United States than in Japan. This study examined similarities and differences in how Japanese and American middle-school science teachers think and feel about inquiry-based teaching. Teachers' attitudes toward the use of inquiry in science teaching were measured through a survey instrument (N=191). Teachers' understanding of inquiry-based teaching was examined through interviews and classroom observations in the United States (N=9) and Japan (N=15). The results show that in spite of the variations in teachers' definitions of inquiry-based teaching, teachers in both countries strongly agree with the idea of inquiry-based teaching. However, little inquiry-based teaching was observed in either of the countries for different reasons. The data indicate that Japanese teachers did not generally help students construct their own understanding of scientific concepts in spite of well-planned lesson structures and activity set-ups. On the other hand, the observational data indicate that American teachers often lacked meaningful science content in spite of their high level of pedagogical knowledge. The need for addressing the importance of scientific concepts in teacher preparation programs in higher education institutions in the US is advocated. To the Japanese science education community, the need for teachers' acquisition of instructional strategies for inquiry-based teaching is strongly addressed.

Teaching Triple Science: GCSE Chemistry

ERIC Educational Resources Information Center

Learning and Skills Network (NJ3), 2007

2007-01-01

The Department for Children, Schools and Families (DCSF) has contracted with the Learning and Skills Network to support awareness and take-up of Triple Science GCSEs through the Triple Science Support Programme. This publication provides an introduction to teaching and learning approaches for the extension topics within GCSE Chemistry. It…

Teaching Triple Science: GCSE Biology

ERIC Educational Resources Information Center

Learning and Skills Network (NJ3), 2007

2007-01-01

The Department for Children, Schools and Families (DCSF) has contracted with the Learning and Skills Network to support awareness and take-up of Triple Science GCSEs through the Triple Science Support Programme. This publication provides an introduction to teaching and learning approaches for the extension topics within GCSE Biology. It highlights…

Incorporating climate change and technology into the science classroom: Lessons from my year as a GK-12 Fellow

NASA Astrophysics Data System (ADS)

Abramoff, R. Z.

2012-12-01

Climate change is not included in the K-8 science standards in Massachusetts; as a result, students learn what climate is, but not how human activities affect it. Starting in 2010, Boston University launched the GK-12 GLACIER program, funded with 2.9M from the National Science Foundation. The purpose of the program is to incorporate the fundamentals of climate change into the K-12 curriculum, focusing on grades 5-8 when quantitative science enters the curriculum. Graduate students are partnered with teachers in Boston public schools for 10 hours a week of teaching with additional curriculum development. I will focus on the curriculum that I developed as a part of this program for the 5th grade science class at The Curley School in Jamaica Plain, MA, where I worked with Grades 3-5, ESL, and PACE autism program science teacher, Stephanie Selznick. The Curley School is an ethnically and economically diverse Boston public school with about 800 students and an 83% minority population. At the Curley, I taught two full days a week, meeting with all of the 5th grade classes and some of the 4th grade classes of all academic levels. The lessons that I created were designed to fit into the state standards and enrich student understanding plant ecology and earth science, as well as develop their capacity to design experiments and use technology. These include Question of the Day, Digital Field Guide to the Outdoor Classroom, Phototropism, Solar System Weather Report, Soil and Water, Local Landforms, and the Earth as a Closed System Unit for which materials and lesson plans are available on my website. Our secondary goals were to improve tech literacy at Curley. Due to funding restrictions, there were few technology resources available to the students at the beginning of the 2011/2012 school year. To improve technology resources at Curley, I organized a fundraiser at Boston University, selling donated items from graduate students and faculty; the 1000 raised was used to supply

Turkish Preservice Science Teachers' Efficacy Beliefs Regarding Science Teaching and Their Beliefs about Classroom Management

ERIC Educational Resources Information Center

Gencer, Ayse Savran; Cakiroglu, Jale

2007-01-01

The purpose of this study was to explore Turkish preservice science teachers' science teaching efficacy and classroom management beliefs. Data in this study were collected from a total number of 584 preservice science teachers utilizing the Science Teaching Efficacy Belief Instrument and the attitudes and beliefs on classroom control (ABCC)…

Reflective Pathways: Analysis of an Urban Science Teaching Field Experience on Noyce Scholar-Science Education Awardees' Decisions to Teach Science in a High-Need New York City School

ERIC Educational Resources Information Center

Bischoff, Paul; French, Paul; Schaumloffel, John

2014-01-01

Awardees of the National Science Foundation's Noyce Scholars funds are required to teach science in high-need urban or rural school districts upon graduation. The purpose of this research was to analyze the reflective considerations that distinguish preservice Noyce Scholar science education majors committed to teaching in high-need New York City…

Getting The Picture: Our Changing Climate- A new learning tool for climate science

NASA Astrophysics Data System (ADS)

Yager, K.; Balog, J. D.

2014-12-01

Earth Vision Trust (EVT), founded by James Balog- photographer and scientist, has developed a free, online, multimedia climate science education tool for students and educators. Getting The Picture (GTP) creates a new learning experience, drawing upon powerful archives of Extreme Ice Survey's unique photographs and time-lapse videos of changing glaciers around the world. GTP combines the latest in climate science through interactive tools that make the basic scientific tenets of climate science accessible and easy to understand. The aim is to use a multidisciplinary approach to encourage critical thinking about the way our planet is changing due to anthropogenic activities, and to inspire students to find their own voice regarding our changing climate The essence of this resource is storytelling through the use of inspiring images, field expedition notes and dynamic multimedia tools. EVT presents climate education in a new light, illustrating the complex interaction between humans and nature through their Art + Science approach. The overarching goal is to educate and empower young people to take personal action. GTP is aligned with national educational and science standards (NGSS, CCSS, Climate Literacy) so it may be used in conventional classrooms as well as education centers, museum kiosks or anywhere with Internet access. Getting The Picture extends far beyond traditional learning to provide an engaging experience for students, educators and all those who wish to explore the latest in climate science.

Teaching Evolution & the Nature of Science.

ERIC Educational Resources Information Center

Farber, Paul

2003-01-01

The theory of evolution provides direction in many fields, such as ecology, genetics, and embryology. Examines issues concerning the teaching of the subject in the United States. Presents a case study approach to teach about the nature of science using the theory of evolution. (SOE)

Preparing perservice teachers to teach elementary school science

NASA Astrophysics Data System (ADS)

Lewis, Amy D.

The development of scientifically literate citizens begins in the elementary school. Yet elementary school teachers are ill prepared to teach science (Trygstad, Smith, Banilower, Nelson, & Horizon Research, Inc., 2013). The research base on teacher preparation finds that programs designed to prepare elementary teachers are inadequate in providing both the content knowledge and pedagogical content knowledge necessary to teach science effectively (Baumgartner, 2010; Bodzin & Beerer, 2003; Bulunuz & Jarrett 2009). This mixed methods study examined what happened when a science methods course was interactively co-taught by an expert in elementary teaching methods and a physics expert. This study also aimed to discover what aspects of the curriculum pre-service teachers (PSTs) said helped them in developing their understanding of science content and scientific reasoning, and how to implement inquiry practices to teach science. A nested case study of three PSTs provided descriptive portraits of student experiences in the class. A whole class case analysis was used to examine what PSTs learned in terms of science, scientific reasoning skills, and pedagogical content knowledge (PCK) from their experiences in the course. It was found that students often conflated science content with the experiences they had in learning the content. Although PSTs felt the interactive co-teaching model effectively created a balance between theory and practice, it was their experiences doing science--conducting physical experiments, developing and discussing scientific models, and the use of inquiry-based instruction--that they credited for their learning. Even with careful curriculum planning, and a course purposely designed to bridge the theory to practice gap, this study found one semester-long methods course to be insufficient in providing the vast content knowledge and PCK elementary school science teachers need.

Teaching Life Sciences to Blind and Visually Impaired Learners

ERIC Educational Resources Information Center

Fraser, William John; Maguvhe, Mbulaheni Obert

2008-01-01

This study reports on the teaching of life sciences (biology) to blind and visually impaired learners in South Africa at 11 special schools with specific reference to the development of science process skills in outcomes-based classrooms. Individual structured interviews were conducted with nine science educators teaching at the different special…

Innovative Technologies in Science Teaching

ERIC Educational Resources Information Center

Guerra, Cecilia; Pombo, Lucia; Moreira, Antonio

2011-01-01

Technology plays a crucial role in pupils' and primary teachers' lives nowadays and its use can facilitate change towards an innovative school environment. The internet, for example, can act as a platform to foster science teaching and offers a variety of opportunities for effective science learning and engaging and motivating children. But…

When climate science became climate politics: British media representations of climate change in 1988.

PubMed

Jaspal, Rusi; Nerlich, Brigitte

2014-02-01

Climate change has become a pressing environmental concern for scientists, social commentators and politicians. Previous social science research has explored media representations of climate change in various temporal and geographical contexts. Through the lens of Social Representations Theory, this article provides a detailed qualitative thematic analysis of media representations of climate change in the 1988 British broadsheet press, given that this year constitutes an important juncture in this transition of climate change from the domain of science to that of the socio-political sphere. The following themes are outlined: (i) "Climate change: a multi-faceted threat"; (ii) "Collectivisation of threat"; (iii) "Climate change and the attribution of blame"; and (iv) "Speculative solutions to a complex socio-environmental problem." The article provides detailed empirical insights into the "starting-point" for present-day disputes concerning climate change and lays the theoretical foundations for tracking the continuities and discontinuities characterising social representations of climate change in the future.

Science Teaching and Learning Activities and Students' Engagement in Science

ERIC Educational Resources Information Center

Hampden-Thompson, Gillian; Bennett, Judith

2013-01-01

The purpose of this analysis is to describe the variation in students' reports of engagement in science across science teaching and learning activities. In addition, this study examines student and school characteristics that may be associated with students' levels of engagement in science. Data are drawn from the Programme for International…

Hands-on approach to teaching Earth system sciences using a information-computational web-GIS portal "Climate"

NASA Astrophysics Data System (ADS)

Gordova, Yulia; Gorbatenko, Valentina; Martynova, Yulia; Shulgina, Tamara

2014-05-01

A problem of making education relevant to the workplace tasks is a key problem of higher education because old-school training programs are not keeping pace with the rapidly changing situation in the professional field of environmental sciences. A joint group of specialists from Tomsk State University and Siberian center for Environmental research and Training/IMCES SB RAS developed several new courses for students of "Climatology" and "Meteorology" specialties, which comprises theoretical knowledge from up-to-date environmental sciences with practical tasks. To organize the educational process we use an open-source course management system Moodle (www.moodle.org). It gave us an opportunity to combine text and multimedia in a theoretical part of educational courses. The hands-on approach is realized through development of innovative trainings which are performed within the information-computational platform "Climate" (http://climate.scert.ru/) using web GIS tools. These trainings contain practical tasks on climate modeling and climate changes assessment and analysis and should be performed using typical tools which are usually used by scientists performing such kind of research. Thus, students are engaged in n the use of modern tools of the geophysical data analysis and it cultivates dynamic of their professional learning. The hands-on approach can help us to fill in this gap because it is the only approach that offers experience, increases students involvement, advance the use of modern information and communication tools. The courses are implemented at Tomsk State University and help forming modern curriculum in Earth system science area. This work is partially supported by SB RAS project VIII.80.2.1, RFBR grants numbers 13-05-12034 and 14-05-00502.

Teaching Historical Geology through a Climate Science Lens

NASA Astrophysics Data System (ADS)

Cleary, P.

2007-12-01

As traditional Geology departments choose to reinvent themselves in light of waning interest in rocks and fossils, waxing interest in environmental, interdisciplinary issues, and advancements in pedagogy that champion inquiry and student based learning, the question begs, "What is to be done with that behemoth, historical geology?" Typically an introductory earth history course presents the timeline background to the origin and evolution of the planet Earth. At UW-Parkside, Origin and History of the Earth is taught from a climatic and dynamic equilibrium perspective using the textbook Earth's Climate Past and Future by William F. Ruddiman. The course is sectioned into 4 parts: 1) Water, Oxygen and Life on Earth, 2) Feedbacks: Greenhouse and Snowball Earth, 3) Mass Extinctions and 4) Present and Future Climate Change. While the course retains a focus upon historical dating and sampling, plate tectonics, the Milankovitch cycles and evolution, students encounter those topics as applied to solving problems reconstructing past climates, assessing the evolution of the past and future atmosphere and investigating mass extinctions. In class, small group work allows us to replace much of the standard passive lecture format with activities and outcomes congruent with a broader, environmentally cohesive picture of the planet, particularly with respect to climate change. The curriculum, activities, outcomes and assessment strategies of this new approach to an ancient class will be discussed. As an introductory course, and possible general education course, the curriculum addresses current issues of climate change to a broader audience than upper level coursework.

Turkish Preservice Science Teachers' Socioscientific Issues-Based Teaching Practices in Middle School Science Classrooms

ERIC Educational Resources Information Center

Genel, Abdulkadir; Topçu, Mustafa Sami

2016-01-01

Background: Despite a growing body of research and curriculum reforms including socioscientific issues (SSI) across the world, how preservice science teachers (PST) or in-service science teachers can teach SSI in science classrooms needs further inquiry. Purpose: The purpose of this study is to describe the abilities of PSTs to teach SSI in middle…

Taking a Closer Look at Science Teaching Orientations

ERIC Educational Resources Information Center

Friedrichsen, Patrica; Van Driel, Jan H.; Abell, Sandra K.

2011-01-01

In this position paper, we examine the science teaching orientation component of the S. Magnusson, J. Krajcik, and H. Borko (1999) pedagogical content knowledge (PCK) model for science teaching. We trace the origin of the construct in the literature, identifying multiple definitions that have lead to ambiguity. After examining published studies…

New Pedagogies on Teaching Science with Computer Simulations

ERIC Educational Resources Information Center

Khan, Samia

2011-01-01

Teaching science with computer simulations is a complex undertaking. This case study examines how an experienced science teacher taught chemistry using computer simulations and the impact of his teaching on his students. Classroom observations over 3 semesters, teacher interviews, and student surveys were collected. The data was analyzed for (1)…

Effective Strategies for Talking about Climate Change in the Classroom

ERIC Educational Resources Information Center

Busch, K. C.; Osborne, Jonathan

2014-01-01

Teaching about climate science presents some unique challenges. Unlike many other science topics, mitigation and adaptation to climate change will require students to take action. This article outlines five major challenges to communicating about climate change in the classroom, drawing on research in environmental psychology: scepticism,…

The integration of creative drama into science teaching

NASA Astrophysics Data System (ADS)

Arieli, Bracha (Bari)

This study explored the inclusion of creative drama into science teaching as an instructional strategy for enhancing elementary school students' understanding of scientific concepts. A treatment group of sixth grade students was taught a Full Option Science System (FOSS) science unit on Mixtures and Solutions with the addition of creative drama while a control group was taught using only the FOSS teaching protocol. Quantitative and qualitative data analyses demonstrated that students who studied science through creative drama exhibited a greater understanding of scientific content of the lessons and preferred learning science through creative drama. Treatment group students stated that they enjoyed participating in the activities with their friends and that the creative drama helped them to better understand abstract scientific concepts. Teachers involved with the creative drama activities were positively impressed and believed creative drama is a good tool for teaching science. Observations revealed that creative drama created a positive classroom environment, improved social interactions and self-esteem, that all students enjoyed creative drama, and that teachers' teaching style affected students' use of creative drama. The researcher concluded that the inclusion of creative drama with the FOSS unit enhanced students' scientific knowledge and understanding beyond that of the FOSS unit alone, that both teachers and students reacted positively to creative drama in science and that creative drama requires more time.

How Constructivist-Based Teaching Influences Students Learning Science

ERIC Educational Resources Information Center

Seimears, C. Matt; Graves, Emily; Schroyer, M. Gail; Staver, John

2012-01-01

The purpose of this article is to provide details about the beneficial processes the constructivist pedagogy has in the area of teaching science. No Child Left Behind could possibly cause detrimental effects to the science classroom and the constructivist teacher, so this essay tells how constructivist-based teaching influences students and their…

How Is Science Being Taught? Measuring Evidence-Based Teaching Practices across Undergraduate Science Departments

PubMed Central

Drinkwater, Michael J.; Matthews, Kelly E.; Seiler, Jacob

2017-01-01

While there is a wealth of research evidencing the benefits of active-learning approaches, the extent to which these teaching practices are adopted in the sciences is not well known. The aim of this study is to establish an evidential baseline of teaching practices across a bachelor of science degree program at a large research-intensive Australian university. Our purpose is to contribute to knowledge on the adoption levels of evidence-based teaching practices by faculty within a science degree program and inform our science curriculum review in practical terms. We used the Teaching Practices Inventory (TPI) to measure the use of evidence-based teaching approaches in 129 courses (units of study) across 13 departments. We compared the results with those from a Canadian institution to identify areas in need of improvement at our institution. We applied a regression analysis to the data and found that the adoption of evidence-based teaching practices differs by discipline and is higher in first-year classes at our institution. The study demonstrates that the TPI can be used in different institutional contexts and provides data that can inform practice and policy. PMID:28232589

Two Challenges to Communicating Climate Science

NASA Astrophysics Data System (ADS)

Oreskes, N.; Evans, J. H.; Feng, J.

2011-12-01

Climate scientists have been frustrated by the persistence of public opinion at odds with established scientific evidence about anthropogenic climate change. Traditionally, scientists have attributed the gap between scientific knowledge and public perception to scientific illiteracy, which could be remedied by a better and more abundant supply of well-communicated scientific information. Social scientific research, however, illustrates that this "deficit model" is insufficient to explain the current state of affairs: many individuals who reject the conclusions of climate scientists are highly educated, and some evidence suggests that, among certain demographics, more educated people are more likely than less educated ones to reject climate science. This talk explores two possible sources of resistance to, or outright rejection of, scientific conclusions about climate change: 1) the effects of long-standing organized efforts to challenge climate science and the credibility of climate scientists; 2) conservative Protestant religious beliefs concerning how factual claims about the earth are determined and how their significance is judged.

Understanding Teaching or Teaching for Understanding: Alternative Frameworks for Science Classrooms.

ERIC Educational Resources Information Center

Wildy, Helen; Wallace, John

1995-01-01

Describes the findings of a study that involved exploring the classroom practices of an experienced physics teacher to enable researchers to reexamine assumptions about good teaching. Asserts that a broader view of good science teaching is needed than that proposed by the constructivist literature. (ZWH)

Teaching Science Using Stories: The Storyline Approach

ERIC Educational Resources Information Center

Isabelle, Aaron D.

2007-01-01

Storytelling is an age-old and powerful means of communication that can be used as an effective teaching strategy in the science classroom. This article describes the authors' experiences implementing the Storyline Approach, an inquiry-based teaching method first introduced by Kieran Egan (1986), in the context of teaching the concept of air…

Emotional Issues in Teaching Science: A Case Study of a Teacher's Views

NASA Astrophysics Data System (ADS)

Zembylas, Michalinos

2004-08-01

Science teaching environments are social environments, and teachers emotions interact with their science teaching in powerful ways. To value the teacher is to value the whole person, not just the intellect. In this paper, a theorization of teacher emotion in science teaching is developed which illustrates the role of emotion in establishing and maintaining self-esteem in science teaching situations. From the standpoint of social-constructionist theory of emotion, it is argued that emotion is a social construction within social relationships. Arising from this view, are the emotions of intellectual excitement, frustration and shame that play a key role in the development of self-esteem. The dynamics of these emotions, in the context of experiences of success and failure, may dispose teachers to act positively or negatively towards science teaching. The theorisation developed is illustrated in the emotional experiences of an elementary school teacher in an early childhood science classroom. These experiences indicate that emotion is constitutive of teaching, and merits greater consideration in science teaching.

Public Perception of Uncertainties Within Climate Change Science.

PubMed

Visschers, Vivianne H M

2018-01-01

Climate change is a complex, multifaceted problem involving various interacting systems and actors. Therefore, the intensities, locations, and timeframes of the consequences of climate change are hard to predict and cause uncertainties. Relatively little is known about how the public perceives this scientific uncertainty and how this relates to their concern about climate change. In this article, an online survey among 306 Swiss people is reported that investigated whether people differentiate between different types of uncertainty in climate change research. Also examined was the way in which the perception of uncertainty is related to people's concern about climate change, their trust in science, their knowledge about climate change, and their political attitude. The results of a principal component analysis showed that respondents differentiated between perceived ambiguity in climate research, measurement uncertainty, and uncertainty about the future impact of climate change. Using structural equation modeling, it was found that only perceived ambiguity was directly related to concern about climate change, whereas measurement uncertainty and future uncertainty were not. Trust in climate science was strongly associated with each type of uncertainty perception and was indirectly associated with concern about climate change. Also, more knowledge about climate change was related to less strong perceptions of each type of climate science uncertainty. Hence, it is suggested that to increase public concern about climate change, it may be especially important to consider the perceived ambiguity about climate research. Efforts that foster trust in climate science also appear highly worthwhile. © 2017 Society for Risk Analysis.

The effect of alternative clinical teaching experience on preservice science teachers' self-efficacy

NASA Astrophysics Data System (ADS)

Klett, Mitchell Dean

The purpose of this study was to compare different methods of alternative clinical experience; family science nights and Saturday science (authentic teaching) against micro-teaching (peer teaching) in terms of self-efficacy in science teaching and teaching self-efficacy. The independent variable, or cause, is teaching experiences (clinical vs. peer teaching); the dependent variable, or effect, is two levels of self-efficacy. This study was conducted at the University of Idaho's main campus in Moscow and extension campus in Coeur d'Alene. Four sections of science methods were exposed to the same science methods curriculum and will have opportunities to teach. However, each of the four sections were exposed to different levels or types of clinical experience. One section of preservice teachers worked with students in a Saturday science program. Another section worked with students during family science nights. The third worked with children at both the Saturday science program and family science nights. The last section did not have a clinical experience with children, instead they taught in their peer groups and acted as a control group. A pre-test was given at the beginning of the semester to measure their content knowledge, teaching self-efficacy and self-efficacy in science teaching. A post-test was given at the end of the semester to see if there was any change in self-efficacy or science teaching self-efficacy. Throughout the semester participants kept journals about their experiences and were interviewed after their alternative clinical teaching experiences. These responses were categorized into three groups; gains in efficacy, no change in efficacy, and drop in efficacy. There was a rise in teaching efficacy for all groups. The mean scores for personal teaching efficacy dropped for the Monday-Wednesday and Tuesday-Thursday group while the both Coeur D'Alene groups remained nearly unchanged. There was no significant change in the overall means for science

Preservice elementary teachers' alternative conceptions of science and their self-efficacy beliefs about science teaching

NASA Astrophysics Data System (ADS)

Koc, Isil

The present study was conducted to investigate the extent to which preservice elementary teachers held alternative conceptions in fundamental elementary science concepts from earth/space science, life science, and physical science along with their self-efficacy beliefs about science teaching and to determine the relationship between these two issues. Eighty-six preservice elementary education majors enrolled in the four sections of the course titled "07E:162 Methods Elementary School Science" offered in the Science Education Center, College of Education, the University of Iowa during the 2005-2006 academic year participated in this study. Twelve preservice elementary teachers participated in follow-up interviews. Data were collected through the use of Alternative Conceptions in Science Instrument constructed by Schoon and Boone (1998), Science Teaching Efficacy Belief Instrument (STEBI-B) constructed by Enochs and Riggs (1990), a participant information form, and through utilization of interviews. The results from the alternative conception instrument indicated that the majority of preservice elementary teachers held a number of alternative conceptions with most being in the physical sciences followed by earth/space, and then life science. Various sources of alternative conceptions emerged during the interview sessions. Participants mainly cited science teachers, science textbooks, and previous science experiences as sources of their alternative conceptions. On the other hand, the analysis of the self-efficacy instrument and follow-up interviews revealed generally positive self-efficacy beliefs. Findings from the study also confirmed that science courses completed in high school and college do not seem to have influenced participants' number and types of alternative conceptions regarding earth/space science, life science, and physical science and self-efficacy beliefs about science teaching. The results also indicate that participants with the lowest number of

Virtual school teacher's science efficacy beliefs: The effects of community of practice on science-teaching efficacy beliefs

NASA Astrophysics Data System (ADS)

Uzoff, Phuong Pham

The purpose of this study was to examine how much K-12 science teachers working in a virtual school experience a community of practice and how that experience affects personal science-teaching efficacy and science-teaching outcome expectancy. The study was rooted in theoretical frameworks from Lave and Wenger's (1991) community of practice and Bandura's (1977) self-efficacy beliefs. The researcher used three surveys to examine schoolteachers' experiences of a community of practice and science-teaching efficacy beliefs. The instrument combined Mangieri's (2008) virtual teacher demographic survey, Riggs and Enochs (1990) Science-teaching efficacy Beliefs Instrument-A (STEBI-A), and Cadiz, Sawyer, and Griffith's (2009) Experienced Community of Practice (eCoP) instrument. The results showed a significant linear statistical relationship between the science teachers' experiences of community of practice and personal science-teaching efficacy. In addition, the study found that there was also a significant linear statistical relationship between teachers' community of practice experiences and science-teaching outcome expectancy. The results from this study were in line with numerous studies that have found teachers who are involved in a community of practice report higher science-teaching efficacy beliefs (Akerson, Cullen, & Hanson, 2009; Fazio, 2009; Lakshmanan, Heath, Perlmutter, & Elder, 2011; Liu, Lee, & Lin, 2010; Sinclair, Naizer, & Ledbetter, 2010). The researcher concluded that school leaders, policymakers, and researchers should increase professional learning opportunities that are grounded in social constructivist theoretical frameworks in order to increase teachers' science efficacy.

Teaching about Climate Change: Cool Schools Tackle Global Warming.

ERIC Educational Resources Information Center

Grant, Tim, Ed.; Littlejohn, Gail, Ed.

Within the last couple of decades, the concentration of greenhouse gases in the atmosphere has increased significantly due to human activities. Today climate change is an important issue for humankind. This book provides a starting point for educators to teach about climate change, although there are obstacles caused by the industrialized…

Collegial Climate and Novice Teachers' Intent to Remain Teaching

ERIC Educational Resources Information Center

Pogodzinski, Ben; Youngs, Peter; Frank, Kenneth A.

2013-01-01

Using survey data from novice teachers across 99 schools, we estimated multilevel regressions to identify the association between novices' intent to remain teaching within their schools and their perceptions of the collegial climate. The results suggest that novice teachers who perceive a more positive collegial climate marked by higher degrees…

Climate Engineering: A Nexus of Ethics, Science and Governance

NASA Astrophysics Data System (ADS)

Ackerman, T. P.

2015-12-01

Climate engineering (or geoengineering) has emerged as a possible component of a strategy to mitigate global warming. This emergence has produced a novel intersection of atmospheric science, environmental ethics and global governance. The scientific questions of climate engineering, while difficult to answer in their own right, are compounded by ethical considerations regarding whether these questions should be addressed and governance questions of how research and deployment could be managed. In an effort to address this intersection of ideas and provide our students with a rich interdisciplinary experience, we (T. Ackerman and S. Gardiner, both senior professors at the University of Washington) taught a cross-listed course in the Atmospheric Sciences and Philosophy departments. The course attracted 12 students (mostly graduate students but with two upper level undergraduates), with roughly equal representation from environmental sciences, ethics, and public policy disciplines, as well as two post-docs. Our primary goal for the course was to develop a functioning research community to address the core issues at the intersection of science and ethics. In this presentation, we discuss the course structure, identify strategies that were successful (or less so), and describe outcomes. We consider this course to be primarily pedagogical in nature, but we also recognize that many of the students in the class, perhaps even a majority, are intending to pursue careers outside academia in areas of public policy, environmental consulting, etc., which added an extra dimension to our class. Here, we also discuss the possibility of developing and teaching such courses in an academic environment that is stressed financially and increasingly dependent on metrics related to class size and student credit hours.

Countering Climate Confusion in the Classroom: New Methods and Initiatives

NASA Astrophysics Data System (ADS)

McCaffrey, M.; Berbeco, M.; Reid, A. H.

2014-12-01

Politicians and ideologues blocking climate education through legislative manipulation. Free marketeers promoting the teaching of doubt and controversy to head off regulation. Education standards and curricula that skim over, omit, or misrepresent the causes, effects, risks and possible responses to climate change. Teachers who unknowingly foster confusion by presenting "both sides" of a phony scientific controversy. All of these contribute to dramatic differences in the quality and quantity of climate education received by U.S. students. Most U.S. adults and teens fail basic quizzes on energy and climate basics, in large part, because climate science has never been fully accepted as a vital component of a 21st-century science education. Often skipped or skimmed over, human contributions to climate change are sometimes taught as controversy or through debate, perpetuating a climate of confusion in many classrooms. This paper will review recent history of opposition to climate science education, and explore initial findings from a new survey of science teachers on whether, where and how climate change is being taught. It will highlight emerging effective pedagogical practices identified in McCaffrey's Climate Smart & Energy Wise, including the role of new initiatives such as the Next Generation Science Standards and Green Schools, and detail efforts of the Science League of America in countering denial and doubt so that educators can teach consistently and confidently about climate change.

Evolving Best Practice in Learning About Air Quality and Climate Change Science in ACCENT

NASA Astrophysics Data System (ADS)

Schuepbach, E.

2008-12-01

Learning about air quality and climate change science has developed into a transdisciplinary impact generator, moulded by academic-stakeholder partnerships, where complementary skills and competences lead to a culture of dialogue, mutual learning and decision-making. These sweeping changes are mirrored in the evolving best practice within the European Network of Excellence on Atmospheric Composition Change (ACCENT). The Training and Education Programme in ACCENT pursues an integrated approach and innovative avenues to sharing knowledge and communicating air quality and climate change science to various end-user groups, including teachers, policy makers, stakeholders, and the general public. Early career scientists are involved in the process, and are trained to acquire new knowledge in a variety of learning communities and environments. Here, examples of both the open system of teaching within ACCENT training workshops for early career scientists, and the engagement of non-academic audiences in the joint learning process are presented.

Co-Teaching as an Approach to Enhance Science Learning and Teaching in Primary Schools

ERIC Educational Resources Information Center

Murphy, Colette; Beggs, Jim

2006-01-01

In this article, we explore some of the experiences of student teachers, classroom teachers, science teacher educators, and children in co-teaching contexts in primary schools. The model of co-teaching adopted enabled student teachers (science specialist), classroom teachers, and university tutors to share expertise and work as equals, without…

Our Changing Climate: A Brand New Way to Study Climate Science

NASA Astrophysics Data System (ADS)

Brey, J. A.; Kauffman, C.; Geer, I.; Nugnes, K. A.; Mills, E. W.

2014-12-01

Earth's climate is inherently variable, but is currently changing at rates unprecedented in recent Earth history. Human activity plays a major role in this change and is projected to do so well into the future. This is the stance taken in Our Changing Climate, the brand new climate science ebook from the American Meteorological Society (AMS). Our Changing Climate investigates Earth's climate system, explores humans' impact on it, and identifies actions needed in response to climate change. Released in August 2014, Our Changing Climate is the result of a year's worth of intensive research and writing, incorporating the latest scientific understandings of Earth's climate system from reports such as IPCC AR5 and the Third National Climate Assessment. To encourage additional exploration of climate science information, scientific literature, from which chapter content was derived, is cited at the conclusion of each chapter. In addition, Topic In Depth sections appear throughout each chapter and lead to more extensive information related to various topics. For example, a Topic In Depth in Chapter 11 describes the effect of climate extremes on ranching enterprises in Nebraska. Climate science is multi-disciplinary and therefore Our Changing Climate covers a breadth of topics. From understanding basic statistics and geospatial tools used to investigate Earth's climate system to examining the psychological and financial reasons behind climate change denial, the AMS believes that a multi-disciplinary approach is the most effective way to increase climate literacy. Our Changing Climate is part of the AMS Climate Studies course which is intended for undergraduate-level students. Other course materials include an eInvestigations Manual and access to the RealTime Climate Portal, both of which provide weekly activities corresponding to that week's chapter content. The RealTime Climate Portal also has links to climate data as well as societal interactions and climate policy

Science teaching self-efficacy in a primary school: A case study

NASA Astrophysics Data System (ADS)

de Laat, Jenny; Watters, James J.

1995-12-01

Bandura's theory of self-efficacy predicts that teachers with high, self-efficacy should persist longer, provide a greater academic focus in child-centred classrooms and exhibit different types of feedback than teachers who have lower self-efficacy. This paper reports on the science teaching self-efficacy in a group of teachers at a state primary school. The research was conducted in two stages using firstly the Science Teaching Efficacy Beliefs Instrument (STEBI-A) to identify cases, and secondly, a semistructured interview coupled with classroom observations. Thirty seven teaching staff were surveyed with the STEBI-A instrument. The five highest and five lowest scoring teachers on the personal science teaching self-efficacy subscale of the STEBI-A were interviewed. The analysis of interviews and observations indicated that teachers with high personal science teaching self-efficacy have had a long interest in science and a relatively strong background of formal science studies with opportunities for exploring out of school activities. Although they may have experienced negative science experiences in their own schooling other ameliorating factors existed which maintained their interest. Their instructional strategies in science lessons were more child-centred than those reported by teachers with lower personal science teaching self-efficacy. The implications of the results for the inservice training of teachers are discussed.

Teaching animal science: education or indoctrination?

PubMed

Schillo, K K

1997-04-01

Traditional animal science curricula ignore sociological aspects of scientific research and therefore portray scientific knowledge as value-free. This view gives rise to a teaching method that involves imparting lists of scientific facts that are to be accepted by students without critical evaluation. This amounts to little more than indoctrination and misrepresents science as a system of knowledge. An alternative approach is based on the view that science is a creative human activity that reflects the values and biases of its practitioners. The goal of this approach is to teach students to think analytically and to make independent judgments about scientific claims. This requires a scientific literacy: an understanding of principal scientific theories, the nature of scientific research, and the relationship between science and society. To achieve this goal, a teacher must become less of an authority figure, whose role is to simply pass on information, and more of a facilitator, whose role is to promote questioning, exploration, and synthesis. This requires a learning community in which students feel comfortable taking risks and develop the courage to make and defend judgments. This teaching approach enhances the intellectual and ethical development of students, allowing them to serve themselves and society in responsible ways.

An Interface between Law and Science: The Climate Change Regime

NASA Astrophysics Data System (ADS)

Kuleshov, Y.; Grandbois, M.; Kaniaha, S.

2012-04-01

Law and Science are jointly building the international climate change regime. Up to date, international law and climate science have been unable to take into consideration both regional law and Pacific climate science in this process. Under the International Climate Change Adaptation Initiative (the Australian Government Initiative to assist with high priority climate adaptation needs in vulnerable countries in the Asia-Pacific region) significant efforts were dedicated to improve understanding of climate in the Pacific through the Pacific Climate Change Science Program (PCCSP) and through the Pacific Adaptation Strategy Assistance Program (PASAP). The first comprehensive PCCSP scientific report on the South Pacific climate has been published in 2011. Under the PASAP, web-based information tools for seasonal climate prediction have been developed and now outputs from dynamical climate model are used in 15 countries of the North-West and South Pacific for enhanced prediction of rainfall, air and sea surface temperatures which reduces countries' vulnerability to climate variability in the context of a changing climate. On a regional scale, the Meteorological and Geohazards Department of Vanuatu is preparing a full report on Climate change impacts on the country. These scientific reports and tools could lead to a better understanding of climate change in the South Pacific and to a better understanding of climate change science, for lawyers and policy-makers. The International climate change regime develops itself according to science findings, and at the pace of the four scientific reports issued by the Intergovernmental Panel on Climate Change (IPCC). In return, Law is a contributing factor to climate change, a structural data in the development and perception of environmental issues and it exerts an influence on Science. Because of the dependency of law on science, the PCCSP and PASAP outcomes will also stimulate and orientate developments in law of the Pacific

NGSS, Climate & Energy: Teaching About Climate Change Without Teaching About Energy Is Like Teaching About Lung Cancer Without Teaching About Smoking

NASA Astrophysics Data System (ADS)

Duggan-Haas, D.

2013-12-01

The ideas of systems pervade the Next Generation Science Standards, and well they should. The title of this abstract, paraphrased from commentator Chris Hayes, bluntly summarizes what should be central to the design of curriculum and instruction in the era of climate change and NGSS. It reflects a systems perspective, highlighting that the relationship between and among scientific topics are as important as the topics themselves. The centrality of systems and of human impacts within systems is highlighted by the fact that within the NGSS, the most connected Disciplinary Core Idea is Earth and Space Sciences - 3: Earth and Human Activity. 'ESS3' appears 457 times and on more than a third of the pages in the pdf of all the performance expectations. The lion's share of these appearances are in the connections boxes below the performance indicators, showing the connections -- the relationships within the Earth system -- of this topic to a multitude of expectations. Deep understandings of climate and climate change require understandings relationships between the atmosphere and human activity, and especially the impacts of energy use. As energy is needed for essentially everything we do, this is a big deal. Yet, in the typical high school science programs today, energy and its relation to climate is not prominent. NGSS has the potential to change that. The Crosscutting Concepts clearly reflect a systems approach, with four of the seven including the word 'system' within their one sentence description. This presentation will address systems in NGSS generally and use the examples from our changing energy system, to highlight ways to address climate and energy in multiple courses at different grade levels. Energy use varies across time and space, and the study of energy ties directly to all of Crosscutting Concepts. We will consider the map, showing aspects of the geography of energy, and historical energy transitions, such as the move from dependence of wood for fuel to

Successful Climate Science Communication Strategies

NASA Astrophysics Data System (ADS)

Sinclair, P.

2016-12-01

In the past decade, efforts to communicate the facts of global change have not successfully moved political leaders and the general public to action. In response, a number of collaborative efforts between scientists and professional communicators, writers, journalists, bloggers, filmmakers, artists and others have arisen seeking to bridge that gap. As a result, a new cadre of science-literate communicators, and media-savvy scientists have made themselves visible across diverse mainstream, traditional, and social media outlets. Because of these collaborations, in recent years, misinformation, and disinformation have been successfully met with accurate and credible rebuttals within a single news cycle.Examples of these efforts is the Dark Snow Project, a science/communication collaboration focusing initially on accelerated arctic melt and sea level rise, and the Climate Science Rapid Response team, which matches professional journalists with appropriate science experts in order to respond within a single news cycle to misinformation or misunderstandings about climate science.The session will discuss successful examples and suggest creative approaches for the future.

Embedding Nature of Science in Teaching about Astronomy and Space

ERIC Educational Resources Information Center

Buaraphan, Khajornsak

2012-01-01

Science teachers need an adequate understanding of nature of science (NOS) and the ability to embed NOS in their teaching. This collective case study aims to explore in-service science teachers' conceptions of NOS and the embeddedness of NOS in their teaching about astronomy and space. Three science teachers participated in this study. All…

Science teachers teaching socioscientific issues (SSI): Four case studies

NASA Astrophysics Data System (ADS)

Lee, Hyunju

Socioscientific issues (SSI) are a class of issues that represent the social, ethical, and moral aspects of science in society. The need for the inclusion of SSI into science curricula has been generally accepted, but relatively few science teachers have incorporated SSI into their courses. Most science teachers feel that their most important task by far is to teach the principles of science, and any substantive pedagogical changes represent a burden. However, there are some teachers who address SSI out of personal initiatives. This dissertation study investigates four high school science teachers who address SSI out of their own initiative and explores their deeper inspirations, values, philosophies, and personal ideals that lead them to teach SSI. The overall approach is based on essentialist methodology (Witz, Goodwin, Hart, & Thomas, 2001; Witz, 2006a) with its focus on "the participant as ally" and "essentialist portraiture." The primary data source is four to six in-depth interviews with individual teachers (about 40-90 minutes for each interview). The interviews are complemented by extensive classroom observations of individual teachers' teaching SSI and by document analysis (including teaching materials, rubrics, student group projects and journals, etc.). There are two major findings. First, the teachers' deeper values and ideals are a source of larger inspiration that plays a significant role in changing their teaching practice. This inspiration may involve higher aspects (e.g., deep concern for students' development, unselfishness, caring, etc.) and commitment. Their teaching represents an integration of their personal experiences, values, concerns, and worldviews, which forms a larger inspiration for teaching. Teaching SSI is a part of this larger process. Second, the current curriculum reforms (STS, SSI, and NOS) only suggest theoretical ideals and do not effectively touch teachers' deeper values and ideals. Basically, the teachers are doing what they

Understanding and managing trust at the climate science-policy interface

NASA Astrophysics Data System (ADS)

Lacey, Justine; Howden, Mark; Cvitanovic, Christopher; Colvin, R. M.

2018-01-01

Climate change effects are accelerating, making the need for appropriate actions informed by sound climate knowledge ever more pressing. A strong climate science-policy relationship facilitates the effective integration of climate knowledge into local, national and global policy processes, increases society's responsiveness to a changing climate, and aligns research activity to policy needs. This complex science-policy relationship requires trust between climate science `producers' and `users', but our understanding of trust at this interface remains largely uncritical. To assist climate scientists and policymakers, this Perspective provides insights into how trust develops and operates at the interface of climate science and policy, and examines the extent to which trust can manage — or even create — risk at this interface.

Science teachers' knowledge, beliefs, values, and concerns of teaching through inquiry

NASA Astrophysics Data System (ADS)

Assiri, Yahya Ibrahim

This study investigated elementary science teachers' knowledge, beliefs, values, and concerns of teaching through inquiry. A mixed-methods research design was utilized to address the research questions. Since this study was designed as a mixed-methods research approach, the researcher gathered two type of data: quantitative and qualitative. The study was conducted in Mohayel School District, Saudi Arabia. The information was collected from 51 participants using a questionnaire with multiple choice questions; also, 11 participants were interviewed. After collecting the data, descriptive and comparative approaches were used. In addition, themes and codes were used to obtain the results. The results indicated that the mean of elementary science teachers' knowledge was 51.23%, which was less than 60% which was the acceptable score. Also, the qualitative results showed that science teachers had a limited background of teaching through inquiry. In addition, the elementary science teachers had a high level of belief to teach science through inquiry since the mean was 3.99 out of 5.00. These quantitative results were confirmed by the qualitative data. Moreover, the overall mean of elementary science teachers was 4.01, which indicated that they believed in the importance of teaching science through inquiry which was also confirmed by the responses of teachers in the interviews. Also, the findings indicated that elementary school science teachers had concerns about teaching science through inquiry since the overall mean was 3.53. In addition, the interviewees mentioned that they faced some obstacles when they teach by inquiry, such as time, resources, class size, and the teachers' background. Generally, the results did not show any significant differences among elementary science teachers' knowledge, beliefs, values, and concerns depending on gender, level of education, and teaching experience. However, the findings indicated there was one significant difference which was

Transformative Science Teaching in Higher Education

ERIC Educational Resources Information Center

Fraser, Sharon P.

2015-01-01

University science teaching remains fairly traditional in its approach, incorporating teacher-centred and lecture-based methodologies and utilizing cook book laboratory experiences. Innovative science lecturers, however, have transformed their understanding and practice as teachers, placing their students at the heart of their actions and engaging…

Science Teaching Methods: A Rationale for Practices

ERIC Educational Resources Information Center

Osborne, Jonathan

2011-01-01

This article is a version of the talk given by Jonathan Osborne as the Association for Science Education (ASE) invited lecturer at the National Science Teachers' Association Annual Convention in San Francisco, USA, in April 2011. The article provides an explanatory justification for teaching about the practices of science in school science that…

Derivation and Implementation of a Model Teaching the Nature of Science Using Informal Science Education Venues

ERIC Educational Resources Information Center

Spector, Barbara S.; Burkett, Ruth; Leard, Cyndy

2012-01-01

This paper introduces a model for using informal science education venues as contexts within which to teach the nature of science. The model was initially developed to enable university education students to teach science in elementary schools so as to be consistent with "National Science Education Standards" (NSES) (1996) and "A Framework for…

Saudi Science Teachers' Views and Teaching Strategies of Socioscientific Issues

NASA Astrophysics Data System (ADS)

Alamri, Aziz S.

Scientific developments such as cloning and nuclear energy have generated many controversial issues pertain to many political, social, environmental, ethical and cultural values in different societies around the globe. These controversies delimited and encircled the potential of including and teaching some important aspects of science in schools and therefore caused less consideration to the influence of these issues on enhancing the scientific literacy of people in general. The purpose of this study was to investigate how Saudi science teachers in the city of Tabuk in Saudi Arabia view and teach SSI in Saudi Arabia. This study employed semi-structured interviews with Saudi science teachers. Methodologically, this study used a constructivist grounded theory as a method for analysis to generate in-depth descriptive data about Saudi science teachers' views and teaching strategies of socio-scientific issues. Some direct and indirect benefits pertain to teaching science, understanding the relationship between science, religion, and society and some other topics are discussed in this study.

Pacific-Australia Climate Change Science and Adaptation Planning program: supporting climate science and enhancing climate services in Pacific Island Countries

NASA Astrophysics Data System (ADS)

Kuleshov, Yuriy; Jones, David; Hendon, Harry; Charles, Andrew; Shelton, Kay; de Wit, Roald; Cottrill, Andrew; Nakaegawa, Toshiyuki; Atalifo, Terry; Prakash, Bipendra; Seuseu, Sunny; Kaniaha, Salesa

2013-04-01

Over the past few years, significant progress in developing climate science for the Pacific has been achieved through a number of research projects undertaken under the Australian government International Climate Change Adaptation Initiative (ICCAI). Climate change has major impact on Pacific Island Countries and advancement in understanding past, present and futures climate in the region is vital for island nation to develop adaptation strategies to their rapidly changing environment. This new science is now supporting new services for a wide range of stakeholders in the Pacific through the National Meteorological Agencies of the region. Seasonal climate prediction is particularly important for planning in agriculture, tourism and other weather-sensitive industries, with operational services provided by all National Meteorological Services in the region. The interaction between climate variability and climate change, for example during droughts or very warm seasons, means that much of the early impacts of climate change are being felt through seasonal variability. A means to reduce these impacts is to improve forecasts to support decision making. Historically, seasonal climate prediction has been developed based on statistical past relationship. Statistical methods relate meteorological variables (e.g. temperature and rainfall) to indices which describe large-scale environment (e.g. ENSO indices) using historical data. However, with observed climate change, statistical approaches based on historical data are getting less accurate and less reliable. Recognising the value of seasonal forecasts, we have used outputs of a dynamical model POAMA (Predictive Ocean Atmosphere Model for Australia), to develop web-based information tools (http://poama.bom.gov.au/experimental/pasap/index.shtml) which are now used by climate services in 15 partner countries in the Pacific for preparing seasonal climate outlooks. Initial comparison conducted during 2012 has shown that the

The influence of field experiences on stages of concern and attitudes of preservice teachers toward science and science teaching

NASA Astrophysics Data System (ADS)

Strawitz, Barbara M.; Malone, Mark R.

The purpose of the study was to determine whether the field experience component of an undergraduate science methods course influenced teachers' concerns and attitudes toward science and science teaching. Age, grade-point average, openmindedness, and school assignment were examined as factors which might explain some of the variance in the dependent measures. A one-group pretest-posttest design was used. Students were administered the Teacher Concerns Questionnaire, the Science Teaching Attitude Scales, and the Rokeach Dogmatism Scale approximately eight weeks after the pretest. Results indicated that field experiences did not significantly change student concerns about teaching science but significantly improved student attitudes toward science and science teaching. Students differing in age, grade-point average, and openmindedness did not difer significantly in changes in concerns and changes in attitude toward science and science teaching. Students assigned to different schools differed significantly in changes in attitude toward science.

The shaping of climate science: half a century in personal perspective

NASA Astrophysics Data System (ADS)

Barry, R. G.

2015-09-01

The paper traces my career as a climatologist from the 1950s and that of most of my graduate students from the late 1960s. These decades were the formative ones in the evolution of climate science. Following a brief account of the history of climatology, a summary of my early training, my initial teaching and research in the UK is discussed. This is followed by new directions at the University of Colorado, Boulder from October 1968. The history of the World Data Center for Glaciology/National Snow and Ice Data Center in Boulder from 1977 is described and climate-cryosphere initiatives at the Cooperative Institute for Research in Environmental Sciences (CIRES). International activities and links are then reported, followed by a section on national and international committees. I then describe my activities during sabbaticals and research leaves. The paper concludes with discussion of my "retirement" activities and an epilogue. The paper is based on a lecture given at the Roger Barry Symposium: A Chronicle of Distinction: From the Arctic to the Andes, at the University of Colorado, 10 August 2004 and updated to 2014.

Teaching Earth Sciences as an interdisciplinary subject: Novel module design involving research literature

NASA Astrophysics Data System (ADS)

Tong, Vincent C. H.

2010-05-01

The study of Earth Sciences requires an interdisciplinary approach as it involves understanding scientific knowledge originating from a wide spectrum of research areas. Not only does it include subjects ranging from, for instance, hydrogeology to deep crustal seismology and from climate science to oceanography, but it also has many direct applications in closely related disciplines such as environmental engineering and natural resources management. While research crossing traditional disciplinary boundaries in geosciences is becoming increasingly common, there is only limited integration of interdisciplinary research in the teaching of the subject. Given that the transition from undergraduate education based on subject modules to postgraduate interdisciplinary research is never easy, such integration is a highly desirable pedagogical approach at both undergraduate and postgraduate levels. My presentation is based on a recent teaching project involving novel design of an undergraduate course. The course is implemented in order to address the synergy between research and teaching (Tong, 2009). This project has been shown to be effective and successful in teaching geosciences undergraduates at the University of London. The module consists of studying core geophysical principles and linking them directly to a selection of recently published research papers in a wide range of interdisciplinary applications. Research reviewing and reporting techniques are systematically developed, practised and fully integrated into teaching of the core scientific theories. A fully-aligned assignment with a feedback website invites the students to reflect on the scientific knowledge and the study skills related to research literature they have acquired in the course. This teaching project has been recognized by a teaching award (http://www.clpd.bbk.ac.uk/staff/BETA). In this presentation, I will discuss how undergraduate teaching with a focus on research literature in Earth Sciences can

Deep Knowledge: Learning to Teach Science for Understanding and Equity. Teaching for Social Justice

ERIC Educational Resources Information Center

Larkin, Douglas B.

2013-01-01

"Deep Knowledge" is a book about how people's ideas change as they learn to teach. Using the experiences of six middle and high school student teachers as they learn to teach science in diverse classrooms, Larkin explores how their work changes the way they think about students, society, schools, and science itself. Through engaging case stories,…

Teacher Beliefs toward Using Alternative Teaching Approaches in Science and Mathematics Classes Related to Experience in Teaching

ERIC Educational Resources Information Center

Isiksal-Bostan, Mine; Sahin, Elvan; Ertepinar, Hamide

2015-01-01

The purpose of this study was to examine the relationships among Turkish classroom, science and mathematics teachers' beliefs toward using inquiry-based approaches, traditional teaching approaches, and technology in their mathematics and science classrooms; their efficacy beliefs in teaching those subjects; and years of experience in teaching in…

Urban High School Teachers' Beliefs Concerning Essential Science Teaching Dispositions

ERIC Educational Resources Information Center

Miranda, Rommel

2012-01-01

This qualitative study addresses the link between urban high school science teachers' beliefs about essential teaching dispositions and student learning outcomes. The findings suggest that in order to help students to do well in science in urban school settings, science teachers should possess essential teaching dispositions which include…

Preservice Science Teacher Beliefs about Teaching and the Science Methods Courses: Exploring Perceptions of Microteaching Outcomes

ERIC Educational Resources Information Center

McLaury, Ralph L.

2011-01-01

This study investigates beliefs about teaching held by preservice science teachers and their influences on self-perceived microteaching outcomes within interactive secondary science teaching methods courses. Hermeneutic methodology was used in cooperation with seven preservice science teachers (N = 7) to infer participant beliefs about teaching…

Using real objects to teach about climate change: an ethnographic perspective

NASA Astrophysics Data System (ADS)

Conner, L.; Perin, S.; Coats, V.; Sturm, M.

2017-12-01

Informal educators frequently use real objects to connect visitors with science content that can otherwise seem abstract. Our NSF-funded project, "Hot Times in Cold Places," leverages this premise to teach about climate change through real objects associated with the nation's only permafrost tunnel, located in Fox, Alaska. We posit that touching real ice, holding Pleistocene bones, and seeing ice wedges in context allows learners to understand climate change in a direct and visceral manner. We are conducting ethnographic research to understand visitor experience at both the tunnel itself and at a permafrost museum exhibit that we are creating as part of the project. Research questions include: 1) What is the nature of visitor talk with respect to explanations about permafrost, tipping points, climate change, and geological time? 2) How do attributes of "realness" (scale, resolution, uniqueness, history and adherence to an original) affect visitor's experience of objects, as perceived through the senses and emotions? We use naturalistic observation, interviews, and videotaping to answer these questions. Analysis focuses on child-to-child talk, reciprocal talk between educator and child, and reciprocal talk between parent and child. Our results elucidate the value of real, vs. replicated and virtual objects, in informal learning, especially in the context of climate change education. An understanding of these factors can help informal learning educators make informed choices about program and exhibit design.

Science Teaching Efficacy of Preservice Elementary Teachers: Examination of the Multiple Factors Reported as Influential

NASA Astrophysics Data System (ADS)

Taştan Kırık, Özgecan

2013-12-01

This study explores the science teaching efficacy beliefs of pr-service elementary teachers and the relationship between efficacy beliefs and multiple factors such as antecedent factors (participation in extracurricular activities and number of science and science teaching methods courses taken), conceptual understanding, classroom management beliefs and science teaching attitudes. Science education majors ( n = 71) and elementary education majors ( n = 262) were compared with respect to these variables. Finally, the predictors of two constructs of science teaching efficacy beliefs, personal science teaching efficacy (PSTE) and science teaching outcome expectancy (STOE), were examined by multiple linear regression analysis. According to the results, participation in extracurricular activities has a significant but low correlation with science concept knowledge, science teaching attitudes, PSTE and STOE. In addition, there is a small but significant correlation between science concept knowledge and outcome expectancy, which leads the idea that preservice elementary teachers' conceptual understanding in science contributes to their science teaching self-efficacy. This study reveals a moderate correlation between science teaching attitudes and STOE and a high correlation between science teaching attitudes and PSTE. Additionally, although the correlation coefficient is low, the number of methodology courses was found to be one of the correlates of science teaching attitudes. Furthermore, students of both majors generally had positive self-efficacy beliefs on both the STOE and PSTE. Specifically, science education majors had higher science teaching self-efficacy than elementary education majors. Regression results showed that science teaching attitude is the major factor in predicting both PSTE and STOE for both groups.

Investigating How Nontraditional Elementary Pre-service Teachers Negotiate the Teaching of Science

NASA Astrophysics Data System (ADS)

Shelton, Mythianne

This qualitative study was designed to investigate the influences on nontraditional preservice teachers as they negotiated the teaching of science in elementary school. Based upon a sociocultural theoretical framework with an identity-in-practice lens, these influences included beliefs about science teaching, life experiences, and the impact of the teacher preparation program. The study sample consisted of two nontraditional preservice teachers who were student teaching in an elementary classroom. Data, collected over a five-month period, included in-depth individual interviews, classroom observations, audio recordings, and reviews of documentations. Interviews focused on the participants' beliefs relating to the teaching of science, prior experiences, and their teacher preparation program experiences relating to the teaching of science. Classroom observations provided additional insights into the classroom setting, participants' teaching strategies, and participants' interactions with the students and cooperating teacher. A whole-text analysis of the interview transcripts, observational field notes, audio recordings and documents generated eight major categories: beliefs about science teaching, role of family, teaching science in the classroom, teacher identity, non-teacher identity, relationships with others, discourses of classroom teaching, and discourses of teachers. The following significant findings emerged from the data: (a) the identity of nontraditional student teachers as science teachers related to early life experiences in science classes; (b) the identity of nontraditional student teachers as science teachers was influenced by their role as parents; (c) nontraditional student teachers learned strategies that supported their beliefs about inquiry learning; and (d) nontraditional student teachers valued the teacher preparation program support system. The results from this qualitative study suggest that sociocultural theory with an identity

Analysing Exemplary Science Teaching

ERIC Educational Resources Information Center

Alsop, Steve, Ed.; Bencze, Larry, Ed.; Pedretti, Erminia, Ed.

2004-01-01

How might exemplary practice be represented by teachers' narratives? How might such representations be analyzed? How might theory and practice be related? "Analyzing Exemplary Science Teaching" is a text that seeks to combine educational theory and practice through analysis of a series of teachers' descriptions of "exemplary"…

Advancing Climate Literacy through Investment in Science Education Faculty, and Future and Current Science Teachers: Providing Professional Learning, Instructional Materials, and a Model for Locally-Relevant and Culturally-Responsive Content

NASA Astrophysics Data System (ADS)

Halversen, C.; Apple, J. K.; McDonnell, J. D.; Weiss, E.

2014-12-01

The Next Generation Science Standards (NGSS) call for 5th grade students to "obtain and combine information about ways individual communities use science ideas to protect Earth's resources and environment". Achieving this, and other objectives in NGSS, will require changes in the educational system for both students and teachers. Teachers need access to high quality instructional materials and continuous professional learning opportunities starting in pre-service education. Students need highly engaging and authentic learning experiences focused on content that is strategically interwoven with science practices. Pre-service and early career teachers, even at the secondary level, often have relatively weak understandings of the complex Earth systems science required for understanding climate change and hold alternative ideas and naïve beliefs about the nature of science. These naïve understandings cause difficulties in portraying and teaching science, especially considering what is being called for in NGSS. The ACLIPSE program focuses on middle school pre-service science teachers and education faculty because: (1) the concepts that underlie climate change align well with the disciplinary core ideas and practices in NGSS for middle grades; and (2) middle school is a critical time for capturing students interest in science as student engagement by eighth grade is the most effective predictor of student pursuit of science in high school and college. Capturing student attention at this age is critical for recruitment to STEM careers and lifelong climate literacy. THE ACLIPSE program uses cutting edge research and technology in ocean observing systems to provide educators with new tools to engage students that will lead to deeper understanding of the interactions between the ocean and climate systems. Establishing authentic, meaningful connections between indigenous and place-based, and technological climate observations will help generate a more holistic perspective

Climate Science Centers: Growing Federal and Academic Expertise in the Nation's Interests

NASA Astrophysics Data System (ADS)

Ryker, S. J.

2014-12-01

The U.S. Department of the Interior's (Interior) natural and cultural resource managers face increasingly complex challenges exacerbated by climate change. In 2009, under Secretarial Order 3289, Interior created eight regional Climate Science Centers managed by the U.S. Geological Survey's (USGS) National Climate Change and Wildlife Science Center and in partnership with universities. Secretarial Order 3289 provides a framework to coordinate climate change science and adaptation efforts across Interior and to integrate science and resource management expertise from Federal, State, Tribal, private, non-profit, and academic partners. In addition to broad research expertise, these Federal/university partnerships provide opportunities to develop a next generation of climate science professionals. These include opportunities to increase the climate science knowledge base of students and practicing professionals; build students' skills in working across the boundary between research and implementation; facilitate networking among researchers, students, and professionals for the application of research to on-the-ground issues; and support the science pipeline in climate-related fields through structured, intensive professional development. In 2013, Climate Science Centers supported approximately 10 undergraduates, 60 graduate students, and 26 postdoctoral researchers. Additional students trained by Climate Science Center-affiliated faculty also contribute valuable time and expertise, and are effectively part of the Climate Science Center network. The Climate Science Centers' education and training efforts have also reached a number of high school students interested in STEM careers, and professionals in natural and cultural resource management. The Climate Science Centers are coordinating to build on each other's successful education and training efforts. Early successes include several intensive education experiences, such as the Alaska Climate Science Center's Girls on

Science Teachers' Perspectives about Climate Change

ERIC Educational Resources Information Center

Dawson, Vaille

2012-01-01

Climate change and its effects are likely to present challenging problems for future generations of young people. It is important for Australian students to understand the mechanisms and consequences of climate change. If students are to develop a sophisticated understanding, then science teachers need to be well-informed about climate change…

Teachers' Ways of Talking about Nature of Science and Its Teaching

ERIC Educational Resources Information Center

Leden, Lotta; Hansson, Lena; Redfors, Andreas; Ideland, Malin

2015-01-01

Nature of science (NOS) has for a long time been regarded as a key component in science teaching. Much research has focused on students' and teachers' views of NOS, while less attention has been paid to teachers' perspectives on NOS teaching. This article focuses on in-service science teachers' ways of talking about NOS and NOS teaching, e.g. what…

Climate Science: A Journalist's View

NASA Astrophysics Data System (ADS)

Roosevelt, M.

2011-12-01

U.S. public opinion polls show that concern over global warming has dropped precipitously in the wake of economic turmoil. With a dearth of climate change coverage on network news, and in large newspapers and magazines, the public largely gets its climate news--and science news generally--from local TV weathermen. At the same time, many local weathercasters have little time to educate themselves about climate change--although the National Science Foundation is funding an effort to inform them. The Heartland Institute and other climate-skeptic organizations are reaching out to TV weathermen, and some prominent weathercasters have embraced the skeptics' arguments, but websites such as Climate Central, and blogs such as DotEarth are seeking to fill the void. The innate caution of climate scientists, most of whom are reluctant to extrapolate from a narrow study on, say, carbon flux or sea ice, to talk about why the planet is in danger is another challenge. For the most part, they don't want to stick their necks out for fear of professional retribution. When scientists limit themselves to talking about narrow results, journalists' eyes glaze over and no one connects the dots. Much attention is devoted to whether or not the media is doing a good job in covering climate change, when energy might better be spent on applying pressure to decision makers? The media can't make legislators vote for progressive climate change policies--only constituents can do that.

On teaching the nature of science: perspectives and resources

NASA Astrophysics Data System (ADS)

Radloff, Jeffrey

2016-06-01