Impact of a Scientist-Teacher Collaborative Model on Students, Teachers, and Scientists

ERIC Educational Resources Information Center

Shein, Paichi Pat; Tsai, Chun-Yen

2015-01-01

Collaborations between the K-12 teachers and higher education or professional scientists have become a widespread approach to science education reform. Educational funding and efforts have been invested to establish these cross-institutional collaborations in many countries. Since 2006, Taiwan initiated the High Scope Program, a high school…

Identity Matching to Scientists: Differences that Make a Difference?

NASA Astrophysics Data System (ADS)

Andersen, Hanne Moeller; Krogh, Lars Brian; Lykkegaard, Eva

2014-06-01

Students' images of science and scientists are generally assumed to influence their related subject choices and aspirations for tertiary education within science and technology. Several research studies have shown that many young people hold rather stereotypical images of scientists, making it hard for them to see themselves as future scientists. Adolescents' educational choices are important aspects of their identity work, and recent theories link individual choice to the perceived match between self and prototypical persons associated with that choice. In the present study, we have investigated images of scientists among the segment of the upper secondary school students (20 % of the cohort) from which future Danish scientists are recruited. Their images were rather realistic, only including vague and predominantly positive stereotypical ideas. With a particular Science-and-Me (SAM) interview methodology, we inquired into the match between self- and prototypical-scientists ( N = 30). We found high perceived similarity within a core of epistemological characteristics, while dissimilarities typically related to a social domain. However, combining interview data with survey data, we found no significant statistical relation between prototype match and aspirations for tertiary education within science and technology. Importantly, the SAM dialogue revealed how students negotiate perceived differences, and we identified four negotiation patterns that all tend to reduce the impact of mismatches on educational aspirations. Our study raises questions about methodological issues concerning the traditional use of self-to-prototype matching as an explanatory model of educational choice.

Addressing the Misconceptions of Middle School Students About Becoming a Scientist or Engineer

NASA Technical Reports Server (NTRS)

Newsom, H. E.; Sorge, C.; Hagerty, J. J.

2000-01-01

Assessment of our educational outreach program shows that students and their parents are excited about space science, but stereotypes about science and scientists drastically effect student attitudes about science and pursuing a technical career.

An Earth System Scientist Network for Student and Scientist Partnerships

NASA Astrophysics Data System (ADS)

Ledley, T. S.

2001-05-01

Successful student and scientist partnerships require that there is a mutual benefit from the partnership. This means that the scientist needs to be able to see the advantage of having students work on his/her project, and the students and teachers need to see that the students contribute to the project and develop the skills in inquiry and the content knowledge in the geosciences that are desired. Through the Earth System Scientist Network (ESSN) for Student and Scientist Partnerships project we are working toward developing scientific research projects for the participation of high school students. When these research projects are developed they will be posted on the ESSN web site that will appear in the Digital Library for Earth System Education (DLESE). In DLESE teachers and students who are interested in participating in a research program will be able to examine the criteria for each project and select the one that matches their needs and situation. In this paper we will report on how the various ESSN research projects are currently being developed to assure that both the scientist and the students benefit from the partnership. The ESSN scientists are working with a team of scientists and educators to 1) completely define the research question that the students will be addressing, 2) determine what role the students will have in the project, 3) identify the data that the students and teachers will work with, 4) map out the scientific protocols that the students will follow, and 5) determine the background and support materials needed to facilitate students successfully participating in the project. Other issues that the team is addressing include 1) identifying the selection criteria for the schools, 2) identifying rewards and recognition for the students and teacher by the scientist, and 3) identifying issues in Earth system science, relevant to the scientists data, that the students and teachers could use as a guide help develop students investigative skills and content knowledge in the geosciences. The importance of fully developing each of these aspects of the ESSN research projects and how they can differ between projects will be discussed.

Toward inclusive science education: University scientists' views of students,instructional practices, and the nature of science

NASA Astrophysics Data System (ADS)

Bianchini, Julie A.; Whitney, David J.; Breton, Therese D.; Hilton-Brown, Bryan A.

2002-01-01

This study examined the perceptions and self-reported practices of 18 scientists participating in a yearlong seminar series designed to explore issues of gender and ethnicity in science. Scientists and seminar were part of the Promoting Women and Scientific Literacy project, a curriculum transformation and professional development initiative undertaken by science, science education, and women's studies faculty at their university. Researchers treated participating scientists as critical friends able to bring clarity to and raise questions about conceptions of inclusion in science education. Through questionnaires and semistructured interviews, we explored their (a) rationales for differential student success in undergraduate science education; (b) self-reports of ways they structure, teach, and assess courses to promote inclusion; and (c) views of androcentric and ethnocentric bias in science. Statistical analysis of questionnaires yielded few differences in scientists' views and reported practices by sex or across time. Qualitative analysis of interviews offered insight into how scientists can help address the problem of women and ethnic minorities in science education; constraints encountered in attempts to implement pedagogical and curricular innovations; and areas of consensus and debate across scientists and science studies scholars' descriptions of science. From our findings, we provided recommendations for other professional developers working with scientists to promote excellence and equity in undergraduate science education.

Exploring Native American Students' Perceptions of Scientists

NASA Astrophysics Data System (ADS)

Laubach, Timothy A.; Crofford, Geary Don; Marek, Edmund A.

2012-07-01

The purpose of this descriptive study was to explore Native American (NA) students' perceptions of scientists by using the Draw-A-Scientist Test and to determine if differences in these perceptions exist between grade level, gender, and level of cultural tradition. Data were collected for students in Grades 9-12 within a NA grant off-reservation boarding school. A total of 133 NA students were asked to draw a picture of a scientist at work and to provide a written explanation as to what the scientist was doing. A content analysis of the drawings indicated that the level of stereotype differed between all NA subgroups, but analysis of variance revealed that these differences were not significant between groups except for students who practised native cultural tradition at home compared to students who did not practise native cultural tradition at home (p < 0.05). The results suggest that NA students who practise cultural traditions at home are more able to function fluidly between indigenous knowledge and modern western science than their non-practising counterparts. Overall, these NA students do not see themselves as scientists, which may influence their educational and career science, technology, engineering, and mathematics paths in the future. The educational implication is that once initial perceptions are identified, researchers and teachers can provide meaningful experiences to combat the stereotypes.

Brain Research: The Necessity for Separating Sites, Actions and Functions.

ERIC Educational Resources Information Center

Meeker, Mary

Educators, as applied scientists, must work in partnership with investigative scientists who are researching brain functions in order to reach a better understanding of gifted students and students who are intelligent but do not learn. Improper understanding of brain functions can cause gross errors in educational placement. Until recently, the…

The impact of a student-teacher-scientist partnership (STSP) on students' and teachers' content knowledge and attitudes toward science

NASA Astrophysics Data System (ADS)

Houseal, Ana K.

Engaging elementary students in science through inquiry-based methodologies is at the center of science education reform efforts (AAAS, 1989, NRC 1996, 2000). Through scientific problem solving, students can learn that science is more than just learning facts and concepts (NRC, 2000) The process of scientific inquiry, as a way of approaching scientific problem solving, can be taught to students through experiential, authentic (or real-world) science experiences. Student-teacher-scientist partnerships (STSPs) are one vehicle used to connect students to these science experiences with practicing research scientists. However, the literature on STSPs demonstrates they are fraught with challenges and very little is known of their effects on teachers' and students' content knowledge growth or changes in their attitudes about science and scientists. This study addressed these two areas by researching a particular STSP. The STSP, called Students, Teachers, and Rangers and Research Scientists (STaRRS), designed to be incorporated into the existing long-standing education program Expedition: Yellowstone! (E:Y!) was the focus of this study. For teachers, a pre-test, intervention, post-test research design addressing content knowledge gains, attitude changes, and pedagogical changes was used. A quasi-experimental pre- post-test design using treatment and comparison groups of students addressed content knowledge gains and attitude changes. Findings provided evidence of significant positive shifts in teachers' attitudes regarding science and scientists, and trends of shifting pedagogical choices made by teachers. Students showed significant content knowledge gains and an increased positive attitude regarding their perceptions of scientists.

Students on Ice: International Polar Year Expeditions

NASA Astrophysics Data System (ADS)

Green, G.

2006-12-01

The Students on Ice program has been introducing and connecting the next generation of Polar researchers and scientists to the Arctic and Antarctic Regions since 1999. To date, approximately 600 international high school and university students have participated on these powerful and award-winning educational expeditions. Traveling through the Antarctic and Arctic on ice-class vessels, the students connect with an international educational team, consisting of Polar scientists, educators, researchers and lecturers, and gain valuable first hand information through a variety of different educational formats. Students participate in lectures, seminars, group discussions, `hands-on' science experiments, and experience once-in-a-lifetime opportunities to view rare wildlife, and to visit remote locations of historic, cultural, and scientific significance. In celebration of the upcoming International Polar Years (IPY), Students on Ice is launching nine unique IPY youth expeditions between 2007 and 2009. Intended for high school students, university students, and interested educators, these expeditions are officially endorsed by the International Polar Year Joint Committee. The goals of the SOI-IPY youth expeditions, include raising awareness and understanding about Polar and environmental issues, development of Polar curriculum and resources, inspiring the next generation of scientists and researchers, and promoting the IPY to millions of youth around through outreach, media and partnership activities.

Assessing the Impact of Education and Outreach Activities on Research Scientists

ERIC Educational Resources Information Center

McCann, Brian M.; Cramer, Catherine B.; Taylor, Lisa G.

2015-01-01

The purpose of this study was to investigate the attitudes of university-level research scientists toward educational and outreach activities that aim to help the general public understand more about their scientific endeavors. Interviews, observations, and survey results from 12 university research scientists, their colleagues, students, and the…

Real-time Science and Educational Collaboration Online from the Indian Ocean

NASA Astrophysics Data System (ADS)

Wilson, R. H.; Sager, W. W.

2007-12-01

During Summer of 2007, scientists and students (via the web) jointly participated in research during the Ninety East Ridge Expedition (cruise KNOX06RR) . Staff organizers from Joint Oceanographic Institutions" JOI Learning and the Integrated Ocean Drilling Program planned and implemented an interactive website to allow students to directly participate with scientists during the site survey aboard the R/V Roger Revelle. Dr. Will Sager and middle school teacher Rory Wilson collaborated daily during the scientific expedition with science team, ship crew and students. From the outset, students were involved and helped to guide the program; this included coming up with the website name and initial design work. Communication with students included the website, individual and group emails and video conferences with student groups. Seven secondary schools from the USA, Europe, India and Thailand participated actively in the project from June to August. Students viewed daily updates on the website, sent in answers for weekly science challenge questions, and interacted with scientists and crew. Student participants learned about navigation, geophysics and petrology, as well as ship operations and technology. Students and educators tracked the expedition's progress in a multi-media environment. Website statistics were recorded; participation began well and increased during the expedition as more people became engaged with the website. All of the crew and scientists wrote self-profiles to help students learn about the range of ocean careers; several of the scientists and graduate students on board wrote or co- authored website articles for students. During this presentation, we will explore and review the major features of the outreach program using the Sea90e website to demonstrate how this real-time interaction engages students in science learning. We will discuss the benefits of collaboration for science and education in our "classroom at sea."

TERRA Education and Public Outreach: Bringing Earth Science Resources to the Public, Students, Educators, and Citizen Scientists

NASA Astrophysics Data System (ADS)

Lewis, N.; Thome, K. J.; Bounoua, L.; Owen, T.

2014-12-01

Leaping advances in the capability to accurately measure global atmospheric and surficial conditions from space have created an abundance of educationally relevant images, discoveries, and products. In attempt to fully utilize these abundant resources, TERRA has allocated a portion of its mission toward education and public outreach. From highly interactive websites allowing users to view the latest satellite images and discoveries, to partnerships with museums encouraging enhanced primary and secondary scholastic experiences, TERRA has successfully applied a multifaceted range of tools to aid in the furthering of education for students, educators, scientists, and the general public. This presentation aims to increase publicity regarding these many methods of outreach, and to highlight particular outreach success stories. With the increasing emphasis on STEM education in current school systems, the invaluable resources and opportunities that TERRA provides for young scientists have become a necessity and will continue to help inspire the next generation of Earth Scientists.

Amazing Muses of Science: An Interdisciplinary Project Creates Awareness of Female Scientists

ERIC Educational Resources Information Center

Carson, Beverly

2016-01-01

This article describes an interdisciplinary project that created awareness of female scientists in a public Montessori classroom. Every spring, the author's sixth-grade students write an educational play in which the entire class participates. Following an underwhelming response to asking students who are their favorite female scientists, the…

Student-Organized College of Education "Educational Research Exchanges" from the Student and Former Student Perspective.

ERIC Educational Resources Information Center

Henson, Robin K.; Guthrie, Abbie

2001-01-01

Discusses how some colleges of education (COEs) attempt to develop academic climate and facilitate graduate student research activity, addressing the role of student-organized internal research conferences in the transformation of student to social scientist and explicating the benefits of these internal conferences to students, faculty, and COEs.…

Online matchmaking: It's not just for dating sites anymore! Connecting the Climate Voices Science Speakers Network to Educators

NASA Astrophysics Data System (ADS)

Wegner, K.; Herrin, S.; Schmidt, C.

2015-12-01

Scientists play an integral role in the development of climate literacy skills - for both teachers and students alike. By partnering with local scientists, teachers can gain valuable insights into the science practices highlighted by the Next Generation Science Standards (NGSS), as well as a deeper understanding of cutting-edge scientific discoveries and local impacts of climate change. For students, connecting to local scientists can provide a relevant connection to climate science and STEM skills. Over the past two years, the Climate Voices Science Speakers Network (climatevoices.org) has grown to a robust network of nearly 400 climate science speakers across the United States. Formal and informal educators, K-12 students, and community groups connect with our speakers through our interactive map-based website and invite them to meet through face-to-face and virtual presentations, such as webinars and podcasts. But creating a common language between scientists and educators requires coaching on both sides. In this presentation, we will present the "nitty-gritty" of setting up scientist-educator collaborations, as well as the challenges and opportunities that arise from these partnerships. We will share the impact of these collaborations through case studies, including anecdotal feedback and metrics.

Online Matchmaking: It's Not Just for Dating Sites Anymore! Connecting the Climate Voices Science Speakers Network to Educators

NASA Technical Reports Server (NTRS)

Wegner, Kristin; Herrin, Sara; Schmidt, Cynthia

2015-01-01

Scientists play an integral role in the development of climate literacy skills - for both teachers and students alike. By partnering with local scientists, teachers can gain valuable insights into the science practices highlighted by the Next Generation Science Standards (NGSS), as well as a deeper understanding of cutting-edge scientific discoveries and local impacts of climate change. For students, connecting to local scientists can provide a relevant connection to climate science and STEM skills. Over the past two years, the Climate Voices Science Speakers Network (climatevoices.org) has grown to a robust network of nearly 400 climate science speakers across the United States. Formal and informal educators, K-12 students, and community groups connect with our speakers through our interactive map-based website and invite them to meet through face-to-face and virtual presentations, such as webinars and podcasts. But creating a common language between scientists and educators requires coaching on both sides. In this presentation, we will present the "nitty-gritty" of setting up scientist-educator collaborations, as well as the challenges and opportunities that arise from these partnerships. We will share the impact of these collaborations through case studies, including anecdotal feedback and metrics.

Examining Educational Climate Change Technology: How Group Inquiry Work with Realistic Scientific Technology Alters Classroom Learning

NASA Astrophysics Data System (ADS)

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

2018-04-01

This study with 79 students in Montreal, Quebec, compared the educational use of a National Aeronautics and Space Administration (NASA) global climate model (GCM) to climate education technologies developed for classroom use that included simpler interfaces and processes. The goal was to show how differing climate education technologies succeed and fail at getting students to evolve in their understanding of anthropogenic global climate change (AGCC). Many available climate education technologies aim to convey key AGCC concepts or Earth systems processes; the educational GCM used here aims to teach students the methods and processes of global climate modeling. We hypothesized that challenges to learning about AGCC make authentic technology-enabled inquiry important in developing accurate understandings of not just the issue but how scientists research it. The goal was to determine if student learning trajectories differed between the comparison and treatment groups based on whether each climate education technology allowed authentic scientific research. We trace learning trajectories using pre/post exams, practice quizzes, and written student reflections. To examine the reasons for differing learning trajectories, we discuss student pre/post questionnaires, student exit interviews, and 535 min of recorded classroom video. Students who worked with a GCM demonstrated learning trajectories with larger gains, higher levels of engagement, and a better idea of how climate scientists conduct research. Students who worked with simpler climate education technologies scored lower in the course because of lower levels of engagement with inquiry processes that were perceived to not actually resemble the work of climate scientists.

Research &Discover: A Pipeline of the Next Generation of Earth System Scientists

NASA Astrophysics Data System (ADS)

Hurtt, G. C.; Einaudi, F.; Moore, B.; Salomonson, V.; Campbell, J.

2006-12-01

In 2002, the University of New Hampshire (UNH) and NASA Goddard Space Flight Center (GSFC) started the educational initiative Research &Discover with the goals to: (i) recruit outstanding young scientists into research careers in Earth science and Earth remote sensing (broadly defined), and (ii) support Earth science graduate students enrolled at UNH through a program of collaborative partnerships with GSFC scientists and UNH faculty. To meet these goals, the program consists of a linked set of educational opportunities that begins with a paid summer research internship at UNH for students following their Junior year of college, and is followed by a second paid summer internship at GSFC for students following their Senior year of college. These summer internships are then followed by two-year fellowship opportunities at UNH for graduate studies jointly supervised by UNH faculty and GSFC scientists. After 5 years of implementation, the program has awarded summer research internships to 22 students, and graduate research fellowships to 6 students. These students have produced more than 78 scientific research presentations, 5 undergraduate theses, 2 Masters theses, and 4 peer-reviewed publications. More than 80% of alums are actively pursuing careers in Earth sciences now. In the process, the program has engaged 19 faculty from UNH and 15 scientists from GSFC as advisors/mentors. New collaborations between these scientists have resulted in new joint research proposals, and the development, delivery, and assessment of a new course in Earth System Science at UNH. Research &Discover represents an educational model of collaboration between a national lab and university to create a pipeline of the next generation of Earth system scientists.

The NASA Climate Change Research Initiative - A Scientist's Perspective

NASA Astrophysics Data System (ADS)

LeGrande, A. N.; Pearce, M. D.; Dulaney, N.; Kelly, S. M.

2017-12-01

For the last four years, I have been a lead mentor in the NASA GISS Climate Change Research Initiative (CCRI) program, a component in the NASA GSFC Office of Education portfolio. It creates a multidisciplinary; vertical research team including a NYC metropolitan teacher, graduate student, undergraduate student, and high school student. While the college and high school members of this research team function like a more traditional internship component, the teacher component provides a powerful, direct way to connect state-of-the art research with students in the classroom. Because the teacher internship lasts a full year, it affords a similar relationship with a teacher that normally only exists between a PhD student and scientist. It also provides an opportunity to train the teacher in using the extensive data archives and other information maintained on NASA's publicly available websites. This time and access provide PhD-level training in the techniques and tools used in my climate research to the high school teacher. The teacher then uses his/her own pedagogical expertise to translate these techniques into age/level appropriate lesson plans for the classroom aligned with current STEM education trends and expectations. Throughout the process, there is an exchange of knowledge between the teacher and scientist that is very similar to the training given to PhD level graduate students. The teacher's understanding of the topic and implementation of the tools is done under a very close collaboration with the scientist supervisor and the NASA Education Program Specialist. This vertical team model encourages collegial communication between teachers and learners from many different educational levels and capitalizes on the efficacy of near peer mentoring strategies. This relationship is important in building trust through the difficult, iterative process that results in the development of highly accurate and quality (continuously discussed and vetted) curriculum composed of science modules on very sophisticated STEM education topics tailored and customized for a high school student audience. This program has thus very meaningful broad impacts with a scientist being able to reach and inspire 150 or more students per year through the expert collaboration of the high school teacher to scientist partnership. PANELIST

ASPIRE: Teachers and researchers working together to enhance student learning

NASA Astrophysics Data System (ADS)

Yager, P. L.; Garay, D. L.; Warburton, J.

2016-02-01

Given the impact of human activities on the ocean, involving teachers, students, and their families in scientific inquiry has never been more important. Science, Technology, Engineering, and Math (STEM) disciplines have become key focus areas in the education community of the United States. Newly adopted across the nation, Next Generation Science Standards require that educators embrace innovative approaches to teaching. Transforming classrooms to actively engage students through a combination of knowledge and practice develops conceptual understanding and application skills. The partnerships between researchers and educators during the Amundsen Sea Polynya International Research Expedition (ASPIRE) offer an example of how academic research can enhance K-12 student learning. In this presentation, we illustrate how ASPIRE teacher-scientist partnerships helped engage students with actual and virtual authentic scientific investigations. Scientists benefit from teacher/researcher collaborations as well, as funding for scientific research also depends on effective communication between scientists and the public. While contributing to broader impacts needed to justify federal funding, scientists also benefit by having their research explained in ways that the broader public can understand: collaborations with teachers produce classroom lessons and published work that generate interest in the scientists' research specifically and in marine science in general. Researchers can also learn from their education partners about more effective teaching strategies that can be transferred to the college level. Researchers who work with teachers in turn gain perspectives on the constraints that teachers and students face in the pre-college classroom. Crosscutting concepts of research in polar marine science can serve as intellectual tools to connect important ideas about ocean and climate science for the public good.

Student Scientist Partnerships: Shrewd Maneuvers.

ERIC Educational Resources Information Center

Tinker, Robert F.

1997-01-01

Explores student-scientist partnerships (SSPs) that help students gain a unique understanding of both the content and the process of science. Discusses the potential of SSPs, the range of SSP activities, a strategy for national impact, the educational importance of SSPs, the research importance of SSPs, and technology as a facilitator. (JRH)

The Educational Attitudes of Private School Educators.

ERIC Educational Resources Information Center

Cookson, Peter W., Jr.

Values about education held by private school educators tend to be those best suited to preparing their mostly middle- and upper-middle-class students for managerial and professional careers. Social scientists have hypothesized that schools readying students for social leadership will stress internalized student behavior norms instead of obedience…

An Analysis of the Impact of Student-Scientist Interaction in a Technology Design Activity, Using the Expectancy-Value Model of Achievement Related Choice

ERIC Educational Resources Information Center

Masson, Anne-Lotte; Klop, Tanja; Osseweijer, Patricia

2016-01-01

Many education initiatives in science and technology education aim to create enthusiasm among young people to pursue a career in Science, Technology, Engineering, and Mathematics (STEM). Research suggests that personal interaction between secondary school students and scientists could be a success factor, but there is a need for more in-depth…

Student Activities in Meteorology: SAM. Version 2.

ERIC Educational Resources Information Center

Meier, Beverly L.; Passarelli, Elisa

The task of providing hands-on as well as minds-on activities for students in science is one of concern to many scientists and educators. In an effort to inspire student interest in science and technology, scientists from the Forecast Systems Laboratory, a laboratory within the National Oceanic and Atmospheric Administration's (NOAA) Environmental…

Where the Wild Microbes Are: Education and Outreach on Sub-Seafloor Microbes

NASA Astrophysics Data System (ADS)

Cooper, S. K.; Kurtz, K.; Orcutt, B.; Strong, L.; Collins, J.; Feagan, A.

2014-12-01

Sub-seafloor microbiology has the power to spark the imaginations of children, students and the general public with its mysterious nature, cutting-edge research, and connections to the search for extraterrestrial life. These factors have been utilized to create a number of educational and outreach products to bring subsurface microbes to non-scientist audiences in creative and innovative ways. The Adopt a Microbe curriculum for middle school students provides hands-on activities and investigations for students to learn about microbes and the on-going research about them, and provides opportunities to connect with active expeditions. A new series of videos engages non-scientists with stories about research expeditions and the scientists themselves. A poster and associated activities explore the nature of science using a microbiologist and her research as examples. A new e-book for young children will engage them with age-appropriate text and illustrations. These projects are multidisciplinary, involve science and engineering practices, are available to all audiences and provide examples of high level and meaningful partnerships between scientists and educators and the kinds of products that can result. Subseafloor microbiology projects such as these, aimed at K-12 students and the general public, have the potential to entice the interest of the next generation of microbe scientists and increase general awareness of this important science.

Graduate Student Support and Manpower Resources in Graduate Science Education, Fall 1970.

ERIC Educational Resources Information Center

National Science Foundation, Washington, DC.

Current data on graduate student support and manpower resources in graduate science education are important to science administrators, educators, and others concerned with the education of highly qualified scientists and engineers and other related manpower issues. They are also of interest to prospective graduate students, vocational counselors,…

Restoration Science in New York Harbor: It takes a (large, diverse and engaged) village

NASA Astrophysics Data System (ADS)

Newton, R.; Birney, L.; Janis, S.; Groome, M.; Palmer, M.; Bone, E.; O'Neil, J. M.; Hill, J.; Dennison, W.; Malinowski, P.; Kohne, L.; Molina, M.; Moore, G.; Woods, N.

2015-12-01

The Curriculum + Community Enterprise for Restoration Science (CCE-RS) facilitates partnerships between scientists and middle school educators on ecological restoration and environmental monitoring projects. The educational model is designed to wrap around the student, including classroom instruction, field science, after-school programs and engagement with the student's community. Its pillars include: a teacher training fellowship at Pace University, student curriculum, a digital platform, afterschool and summer mentoring, and community exhibits. The digital platform includes a tablet app tailored to the project's field protocols and linked to a database shared across schools and partnering institutions. Through the digital platform, data is integrated into a single citizen-science monitoring project, teachers share curriculum and best practices, and students link directly to their peers at other schools. Curriculum development has been collaborative between scientists, science education specialists, and secondary school teachers. The CCE-RS is rooted in project-based learning: the New York Harbor School has engaged high school students in environmental monitoring and oyster restoration in the Harbor for about the last decade. The science partners (U. of Maryland and Columbia) have been working with students and other citizen scientists in outdoor science over about the last decade. Local partners in outside-the-classroom education include the New York Academy of Sciences, The River Project, which will provide field education services, and Good Shepherd Services, which provides after-school programming in schools serving primarily poor families. Scientists on the project engage directly with teachers and informal educators in curriculum development and citizen-science outreach. We present the lessons learned from our first cohort of Fellows, the pedagogical model, and the digital platform, which is extensible to other ecological restoration settings.

CosmoQuest: Training Educators and Engaging Classrooms in Citizen Science through a Virtual Research Facility

NASA Astrophysics Data System (ADS)

Buxner, Sanlyn; Bracey, Georgia; Summer, Theresa; Cobb, Whitney; Gay, Pamela L.; Finkelstein, Keely D.; Gurton, Suzanne; Felix-Strishock, Lisa; Kruse, Brian; Lebofsky, Larry A.; Jones, Andrea J.; Tweed, Ann; Graff, Paige; Runco, Susan; Noel-Storr, Jacob; CosmoQuest Team

2016-10-01

CosmoQuest is a Citizen Science Virtual Research Facility that engages scientists, educators, students, and the public in analyzing NASA images. Often, these types of citizen science activities target enthusiastic members of the public, and additionally engage students in K-12 and college classrooms. To support educational engagement, we are developing a pipeline in which formal and informal educators and facilitators use the virtual research facility to engage students in real image analysis that is framed to provide meaningful science learning. This work also contributes to the larger project to produce publishable results. Community scientists are being solicited to propose CosmoQuest Science Projects take advantage of the virtual research facility capabilities. Each CosmoQuest Science Project will result in formal education materials, aligned with Next Generation Science Standards including the 3-dimensions of science learning; core ideas, crosscutting concepts, and science and engineering practices. Participating scientists will contribute to companion educational materials with support from the CosmoQuest staff of data specialists and education specialists. Educators will be trained through in person and virtual workshops, and classrooms will have the opportunity to not only work with NASA data, but interface with NASA scientists. Through this project, we are bringing together subject matter experts, classrooms, and informal science organizations to share the excitement of NASA SMD science with future citizen scientists. CosmoQuest is funded through individual donations, through NASA Cooperative Agreement NNX16AC68A, and through additional grants and contracts that are listed on our website, cosmoquest.org.

Learning with Teachers; A Scientist's Perspective

NASA Astrophysics Data System (ADS)

Czajkowski, K. P.

2004-12-01

Over the past six years, as an Assistant Professor and now as an Associate Professor, I have engaged in educational outreach activities with K-12 teachers and their students. In this presentation I will talk about the successes and failures that I have had as a scientist engaged in K-12 educational outreach, including teaching the Earth System Science Education Alliance (ESSEA) distance learning course, teaching inquiry-based science to pre-service teachers through the NASA Opportunities for Visionary Academics (NOVA) program, GLOBE, school visits, and research projects with teachers and students. I will reflect on the potential impact this has had on my career, negative and positive. I will present ways that I have been able to engage in educational outreach while remaining a productive scientist, publishing research papers, etc. Obtaining grant funding to support a team of educational experts to assist me perform outreach has been critical to my groups success. However, reporting for small educational grants from state agencies can often be overwhelming. The bottom line is that I find working with teachers and students rewarding and believe that it is a critical part of me being a scientist. Through the process of working with teachers I have learned pedagogy that has helped me be a better teacher in the university classroom.

Web site lets solar scientists inform and inspire students

NASA Astrophysics Data System (ADS)

Hauck, Karin

2012-07-01

Where on the Web can a middle school girl ask a female solar scientist about solar storms, the course and behavior of charged solar particles, and the origin of the Sun's dynamo—and also find out what the scientist was like as a child, whether the scientist has tattoos or enjoys snowboarding, what she likes and dislikes about her career, and how she balances her energy for work and family life? These kinds of exchanges happen at Solar Week (http://www.solarweek.org; see Figure 1). Established in 2000, Solar Week is an online resource for middle and lower high school students about the science of the Sun, sponsored by the Center for Science Education at the Space Sciences Laboratory (CSE@SSL) at the University of California, Berkeley (UC Berkeley). The Web site's goals are to educate students about the Sun and solar physics and to encourage future careers in science—especially for girls. One way is by giving solar scientists the chance to be relatable role models, to answer students' questions, and to share their experiences in an online forum.

Inspiring the Next Generation of Explorers: Scientist Involvement in the Expedition Earth and Beyond Program

NASA Astrophysics Data System (ADS)

Graff, P. V.; Stefanov, W. L.; Willis, K.; Runco, S.

2012-12-01

Scientists, science experts, graduate and even undergraduate student researchers have a unique ability to inspire the next generation of explorers. These science, technology, engineering, and mathematics (STEM) experts can serve as role models for students and can help inspire them to consider future STEM-related careers. They have an exceptional ability to instill a sense of curiosity and fascination in the minds of students as they bring science to life in the classroom. Students and teachers are hungry for opportunities to interact with scientists. They feel honored when these experts take time out of their busy day to share their science, their expertise, and their stories. The key for teachers is to be cognizant of opportunities to connect their students with scientists. For scientists, the key is to know how to get involved, to have options for participation that involve different levels of commitment, and to work with educational specialists who can help facilitate their involvement. The Expedition Earth and Beyond (EEAB) Program, facilitated by the Astromaterials Research and Exploration Science (ARES) Directorate at the NASA Johnson Space Center, is an Earth and planetary science education program designed to inspire, engage, and educate teachers and students by getting them actively involved with NASA exploration, discovery, and the process of science. One of the main goals of the program is to facilitate student research in the classroom. The program uses astronaut photographs, provided through the ARES Crew Earth Observations (CEO) payload on the International Space Station (ISS) as the hook to help students gain an interest in a research topic. Student investigations can focus on Earth or involve comparative planetology. Student teams are encouraged to use additional imagery and data from Earth or planetary orbital spacecraft, or ground-based data collection tools, to augment the astronaut photography dataset. A second goal of the program is to provide opportunities for meaningful connections between scientists and classrooms. To do this, EEAB offers multiple opportunities for scientist involvement. One opportunity involves having scientists work as mentors for student teams conducting research. These student teams, ranging from grades 4 through 12, are able to obtain guidance, suggestions, and input from STEM experts as they conduct a research investigation. Another opportunity for scientist involvement is participation in Classroom Connection Distance Learning (DL) events. These DL events entail interactive and engaging presentations that enable STEM experts to share their expertise with students and teachers (grades 3 through 12) from all across the nation. A third opportunity for scientist involvement involves participation in virtual student team science presentations. Student teams have the opportunity to share their research and results by presenting it to science experts through the use of WebEx, an easy-to-use online conferencing tool. The impact STEM experts have on students in today's classrooms is powerful. They serve as role models to these students, and they open students' eyes to a potential career path they may not have known existed otherwise. The more scientists and STEM experts we can connect with students, the greater the impact we can make as we strive to inspire and prepare our nation's next generation of explorers.

Inspiring the Next Generation of Explorers: Scientist Involvement in the Expedition Earth and Beyond Program

NASA Technical Reports Server (NTRS)

Graff, Paige; Stefanov, William; Willis, Kim; Runco, Susan

2012-01-01

Scientists, science experts, graduate and even undergraduate student researchers have a unique ability to inspire the next generation of explorers. These science, technology, engineering, and mathematics (STEM) experts can serve as role models for students and can help inspire them to consider future STEM-related careers. They have an exceptional ability to instill a sense of curiosity and fascination in the minds of students as they bring science to life in the classroom. Students and teachers are hungry for opportunities to interact with scientists. They feel honored when these experts take time out of their busy day to share their science, their expertise, and their stories. The key for teachers is to be cognizant of opportunities to connect their students with scientists. For scientists, the key is to know how to get involved, to have options for participation that involve different levels of commitment, and to work with educational specialists who can help facilitate their involvement. The Expedition Earth and Beyond (EEAB) Program, facilitated by the Astromaterials Research and Exploration Science (ARES) Directorate at the NASA Johnson Space Center, is an Earth and planetary science education program designed to inspire, engage, and educate teachers and students by getting them actively involved with NASA exploration, discovery, and the process of science. One of the main goals of the program is to facilitate student research in the classroom. The program uses astronaut photographs, provided through the ARES Crew Earth Observations (CEO) payload on the International Space Station (ISS) as the hook to help students gain an interest in a research topic. Student investigations can focus on Earth or involve comparative planetology. Student teams are encouraged to use additional imagery and data from Earth or planetary orbital spacecraft, or ground-based data collection tools, to augment the astronaut photography dataset. A second goal of the program is to provide opportunities for meaningful connections between scientists and classrooms. To do this, EEAB offers multiple opportunities for scientist involvement. One opportunity involves having scientists work as mentors for student teams conducting research. These student teams, ranging from grades 4 through 12, are able to obtain guidance, suggestions, and input from STEM experts as they conduct a research investigation. Another opportunity for scientist involvement is participation in Classroom Connection Distance Learning (DL) events. These DL events entail interactive and engaging presentations that enable STEM experts to share their expertise with students and teachers (grades 3 through 12) from all across the nation. A third opportunity for scientist involvement involves participation in virtual student team science presentations. Student teams have the opportunity to share their research and results by presenting it to science experts through the use of WebEx, an easy-to-use online conferencing tool. The impact STEM experts have on students in today s classrooms is powerful. They serve as role models to these students, and they open students eyes to a potential career path they may not have known existed otherwise. The more scientists and STEM experts we can connect with students, the greater the impact we can make as we strive to inspire and prepare our nation s next generation of explorers.

Bringing Hands-on Activities and Real Scientists to Students: Bishop Museum's X-treme Science Exhibit, Holoholo Science Program, and Planned Science Learning Center

NASA Astrophysics Data System (ADS)

Hills, D. J.; Fullerton, K.; Hoddick, C.; Ali, N.; Mosher, M. K.

2002-12-01

Bishop Museum developed the "X-treme Science: Exploring Oceans, Volcanoes, and Outer Space" museum exhibit in conjunction with NASA as part of their goal to increase educational outreach. A key element of the exhibit was the inclusion of real scientists describing what they do, and fostering the interaction between scientists and students. Highlights of the exhibit were interviews with local (Hawaii-based) scientists involved in current ocean, volcano, and space research. These interviews were based on questions that students provided, and were available during the exhibit at interactive kiosks. Lesson plans were developed by local teachers and scientists, and provided online to enhance the exhibit. However, one limitation of the museum exhibit was that not all students in the state could visit, or spend enough time with it. To serve more remote schools, and to provide for additional enrichment for those who did attend, the education department at Bishop Museum developed a traveling program with the X-treme Science exhibit as the basis. The Holoholo (Hawaiian for "fun outing") Science program brings a scientist into the classroom with a hands-on scientific inquiry activity. The activity is usually a simplified version of a problem that the scientist actually deals with. The students explore the activity, reach conclusions, and discuss their results. They are then given the opportunity to question the scientist about the activity and about what the scientist does. This allows students to understand that science is not something mystical, but rather something attainable. A key element of Holoholo remains the active participation of real-life scientists in the experience. The scientists who have participated in the program have had overwhelmingly positive experiences. Bishop Museum is developing a science learning center, with the objective of meeting local and national science standards using inquiry based science. The unifying theme of all three of these projects is involving students with active scientists who are accessible to them. AGU scientists are vital to realizing this goal.

Growing scientists: A partnership between a university and a school district

NASA Astrophysics Data System (ADS)

Woods, Teresa Marie

Precollege science education in the United States has virtually always been influenced by university scientists to one degree or another. Partnership models for university scientist---school district collaborations are being advocated to replace outreach models. Although the challenges for such partnerships are well documented, the means of fostering successful and sustainable science education partnerships are not well studied. This study addresses this need by empirically researching a unique scientist-educator partnership between a university and a school district utilizing case study methods. The development of the partnership, emerging issues, and multiple perspectives of participants were examined in order to understand the culture of the partnership and identify means of fostering successful science education partnerships. The findings show the partnership was based on a strong network of face-to-face relationships that fostered understanding, mutual learning and synergy. Specific processes instituted ensured equity and respect, and created a climate of trust so that an evolving common vision was maintained. The partnership provided synergy and resilience during the recent economic crisis, indicating the value of partnerships when public education institutions must do more with less. High staff turnover, however, especially of a key leader, threatened the partnership, pointing to the importance of maintaining multiple-level integration between institutions. The instrumental roles of a scientist-educator coordinator in bridging cultures and nurturing the collaborative environment are elucidated. Intense and productive collaborations between teams of scientists and educators helped transform leading edge disciplinary science content into school science learning. The innovative programs that resulted not only suggest important roles science education partnerships can play in twenty-first century learning, but they also shed light on the processes of educational innovation itself. Further, the program and curriculum development revealed insights into areas of teaching and learning. Multiple perspectives of participants were considered in this study, with student perspectives demonstrating the critical importance of investigating student views in future studies. When educational institutions increasingly need to address a diverse population, and scientists increasingly want to recruit diverse students into the fields of science, partnerships show promise in creating a seamless K-20+ continuum of science education.

Science and Exploration in the Classroom & Beyond: An Interdisciplinary STEAM Curriculum Developed by SSERVI Educators & Scientists

NASA Astrophysics Data System (ADS)

Becker, Tracy M.; Runyon, Cassandra; Cynthia, Hall; Britt, Daniel; Tracy Becker

2017-10-01

Through NASA’s Solar System Exploration Research Virtual Institute (SSERVI), the Center for Lunar and Asteroid Surface Science (CLASS) and the SSERVI Evolution and Environment of Exploration Destinations (SEEED) nodes have developed an interdisciplinary formal and informal hands-on curriculum to bring the excitement of space exploration directly to the students.With a focus on exploring asteroids, this 5-year effort has infused art with traditional STEM practices (creating STEAM) and provides teachers with learning materials to incorporate art, social studies, English language arts, and other courses into the lesson plans. The formal curricula being developed follows Next Generation Standards and incorporates effective and engaging pedagogical strategies, such as problem-based learning (PBL), design thinking, and document based questions, using authentic data and articles, some of which are produced by the SSERVI scientists. From the materials developed for the formal education component, we have built up a collection of informal activities of varying lengths (minutes to weeks-long programs) to be used by museums, girl and boy scouts, science camps, etc.The curricula are being developed by formal and informal educators, artists, storytellers, and scientists. The continual feedback between the educators, artists, and scientists enables the program to evolve and mature such that the material will be accessible to the students without losing scientific merit. Online components will allow students to interact with SSERVI scientists and will ultimately infuse ongoing, exciting research into the student’s lessons.Our Education & Public Engagement (EPE) program makes a strong effort to make educational material accessible to all learners, including those with visual or hearing impairments. Specific activities have been included or independently developed to give all students an opportunity to experience the excitement of the universe.

Engaging Scientists in K-12 Professional Development and Curriculum Development in the Context of Alaska's Large Marine Ecosystems

NASA Astrophysics Data System (ADS)

Sigman, M.; Anderson, A.; Deans, N. L.; Dublin, R.; Dugan, D.; Matsumoto, G. I.; Warburton, J.

2012-12-01

Alaska marine ecosystem-based professional development workshops have proven to be a robust context for engaging scientists from a variety of disciplines in overcoming barriers to communication and collaboration among scientists and educators. Scientists came away from scientist-teacher workshops with effective K-12 outreach strategies as well as a deeper understanding about how to contribute meaningfully to K-12 education. The establishment of the Alaskan Center for Ocean Sciences Education Excellence (COSEE-AK) in 2009 was the catalyst for a series of professional development workshops related to the North Pacific Research Board's (NPRB) marine focus areas (Bering Sea/Aleutian Islands, Gulf of Alaska, and Arctic Ocean) for Integrated Ecosystem Research Programs (IERPs). During 2010-2012, COSEE-AK and NPRB partnered with the Arctic Research Consortium of the U.S. (ARCUS), the Alaska Ocean Observing System (AOOS), and the Monterey Bay Aquarium Research Institute (MBARI) to support a five-day professional development workshop focused on each ecosystem. The workshops brought together three types of participants: 1) Alaska-focused marine ecosystem scientists; 2) rural Alaskan teachers living within each ecosystem; and 3) teachers from outside Alaska who had research experiences with scientists in the ecosystem. Over the course of the workshops, we developed a workshop model with four objectives: 1) to increase the science content knowledge of educators and their ability to teach ecosystem science; 2) to provide the scientists an opportunity to have broader impacts from their research on educators and Alaska Native and rural students; 3) to increase the knowledge and skills of educator and scientist participants to provide effective learning experiences for K-12 students; and 4) to facilitate the collaborative development of lesson plans. A total of 28 scientists and 41 educators participated in the three workshops. The success of the workshop for the educators was evaluated by pre- and post-workshop surveys of their perceived increase in content knowledge in specific topics and increased confidence in teaching those topics. The experiences of the scientists were evaluated based on recorded one-on-one interviews. Preliminary results indicate that the Arctic Ocean workshop was the most successful of the three in meeting the workshop objectives for both teacher and scientist participants. The gain in teachers' level of knowledge and confidence was significant for five scientific topics. Scientists reported gains in their understanding of K-12 education, working with teachers, lesson plan design, and how to make their science relevant to Alaska Native students and communities. A comparison of scientists responses from all three workshops indicate that the factors unique to the Arctic Ocean Workshop which contributed to meeting the workshop objectives in terms of scientist engagement were: 1) the sustained involvement of the scientists throughout the workshop, 2) an effective ratio of scientists to teachers (1:1), with flexibility for smaller group work), and 3) the involvement of Alaska Native scientists, educators, and community members in the collaborative work. The lesson plans have been posted to the ARCUS (http://www.polartrec.com) and MBARI (http://www.mbari/earth) websites.

Using the Draw-a-Scientist Test for Inquiry and Evaluation

ERIC Educational Resources Information Center

Miele, Eleanor

2014-01-01

The Draw-a-Scientist Test (DAST) is a tool to assess stereotypical imagery of scientists. This paper describes the use of the DAST as both a model for inquiry and as a method of assessing the affective domain. The DAST was administered in a science education methods course for undergraduate students of elementary education, a methods course for…

Sun-Earth Scientists and Native Americans Collaborate on Sun-Earth Day

NASA Astrophysics Data System (ADS)

Ng, C. Y.; Lopez, R. E.; Hawkins, I.

2004-12-01

Sun-Earth Connection scientists have established partnerships with several minority professional societies to reach out to the blacks, Hispanics and Native American students. Working with NSBP, SACNAS, AISES and NSHP, SEC scientists were able to speak in their board meetings and national conferences, to network with minority scientists, and to engage them in Sun-Earth Day. Through these opportunities and programs, scientists have introduced NASA research results as well indigenous views of science. They also serve as role models in various communities. Since the theme for Sun-Earth Day 2005 is Ancient Observatories: Timeless Knowledge, scientists and education specialists are hopeful to excite many with diverse backgrounds. Sun-Earth Day is a highly visible annual program since 2001 that touches millions of students and the general public. Interviews, classroom activities and other education resources are available on the web at sunearthday.nasa.gov.

The Perceptions of Five Years Old Group Students' about Scientists

ERIC Educational Resources Information Center

Zeynep Et, Sümeyra; Memis, Esra Kabatas

2017-01-01

The purpose of this research is to reveal the perceptions of students of five years old group about scientists. The practice was implemented with 76 students having education in five-age group continuing to various nursery schools located in the center of Kastamonu province. Before starting the practice, the teacher asked the questions of…

Impact of a Student-Teacher-Scientist Partnership on Students' and Teachers' Content Knowledge, Attitudes toward Science, and Pedagogical Practices

ERIC Educational Resources Information Center

Houseal, Ana K.; Abd-El-Khalick, Fouad; Destefano, Lizanne

2014-01-01

Engaging K-12 students in science-based inquiry is at the center of current science education reform efforts. Inquiry can best be taught through experiential, authentic science experiences, such as those provided by Student-Teacher-Scientist Partnerships (STSPs). However, very little is known about the impact of STSPs on teachers' and…

Education and training of future wetland scientists and managers

USGS Publications Warehouse

Wilcox, D.A.

2008-01-01

Wetland science emerged as a distinct discipline in the 1980s. In response, courses addressing various aspects of wetland science and management were developed by universities, government agencies, and private firms. Professional certification of wetland scientists began in the mid-1990s to provide confirmation of the quality of education and experience of persons involved in regulatory, management, restoration/construction, and research involving wetland resources. The education requirements for certification and the need for persons with specific wetland training to fill an increasing number of wetland-related positions identified a critical need to develop curriculum guidelines for an undergraduate wetland science and management major for potential accreditation by the Society of Wetland Scientists. That proposed major contains options directed toward either wetland science or management. Both options include required basic courses to meet the general education requirements of many universities, required upper-level specialized courses that address critical aspects of physical and biological sciences applicable to wetlands, and a minimum of four additional upper-level specialized courses that can be used to tailor a degree to students' interests. The program would be administered by an independent review board that would develop guidelines and evaluate university applications for accreditation. Students that complete the required coursework will fulfill the education requirements for professional wetland scientist certification and possess qualifications that make them attractive candidates for graduate school or entry-level positions in wetland science or management. Universities that offer this degree program could gain an advantage in recruiting highly qualified students with an interest in natural resources. Alternative means of educating established wetland scientists are likewise important, especially to provide specialized knowledge and experience or updates related to new management discoveries, policies, and regulations. ?? 2008 The Society of Wetland Scientists.

A workshop on leadership for MD/PhD students

PubMed Central

Ciampa, Erin j.; Hunt, Aubrey A.; Arneson, Kyle O.; Mordes, Daniel A.; Oldham, William M.; Vin Woo, Kel; Owens, David A.; Cannon, Mark D.; Dermody, Terence S.

2011-01-01

Success in academic medicine requires scientific and clinical aptitude and the ability to lead a team effectively. Although combined MD/PhD training programs invest considerably in the former, they often do not provide structured educational opportunities in leadership, especially as applied to investigative medicine. To fill a critical knowledge gap in physician-scientist training, the Vanderbilt Medical Scientist Training Program (MSTP) developed a biennial two-day workshop in investigative leadership. MSTP students worked in partnership with content experts to develop a case-based curriculum and deliver the material. In its initial three offerings in 2006, 2008, and 2010, the workshop was judged by MSTP student attendees to be highly effective. The Vanderbilt MSTP Leadership Workshop offers a blueprint for collaborative student-faculty interactions in curriculum design and a new educational modality for physician-scientist training. PMID:21841905

The transformative experiences of a scientist-professor with teacher candidates

NASA Astrophysics Data System (ADS)

Lashley, Terry Lee Hester

This case study documented the pedagogical and philosophical change experiences of a senior research scientist-professor at a large Research I University as he implemented an open inquiry immersion course with secondary science teacher candidates. The 4-semester hour graduate-level credit course (Botany 531) is titled "Knowing and Teaching Science: Just Do-It!" The students were 5th-year education students who possessed an undergraduate degree in the biological sciences. The premise for the course is that to teach science effectively, one must be able to DO science. Students were provided with extensive opportunities to design and carry out experiments and communicate the results both orally and in a written format. The focus of this dissertation was on changes in the pedagogical philosophy and practice of the scientist-professor as he taught this course over a 4-year period, 1997--2000. The data used in this study include the scientist-professor's reflective journals (1997--2000), the students' journals (1997--2000), and interviews with the scientist-professor (2001--2002). HyperRESEARCH 2.03 software was used to code and analyze the reflective journals and transcribed interviews. Data were reviewed and then placed into original codes. The codes were then grouped into themes for analysis. Identified themes included (1) Reflective Practice, (2) Social Construction of Knowledge, (3) Legitimate Peripheral Participation, and (4) the Zone of Proximal Development. There is clear evidence that the scientist-professor experienced transformative changes in his philosophy and practice over the 4-year period. This is shown by (1) differences in learning outcomes and expectations for Do-It! course students and traditional course students, (2) documentation of the scientist-professor's movement through the Concerns Based Adoption Model (CBAM) Stages of Concern, (3) increased collaboration and support from the college of education, (4) development and delivery of two other courses patterned after the Do-It! course, (5) interest and participation in education research, (6) presentation and participation in national and regional science education conferences, and (7) efforts to influence colleagues regarding teaching and learning. Furthermore, questioning strategies are an instructional strategy and dialogue is a component of all his university courses. Moreover, his professional research interest includes science pedagogy and he coauthors research articles with science educators.

Scientists Involved in K-12 Education

NASA Astrophysics Data System (ADS)

Robigou, V.

2004-12-01

The publication of countless reports documenting the dismal state of science education in the 1980s, and the Third International Mathematics and Science Study (TIMMS) report (1996) called for a wider involvement of the scientific community in K-12 education and outreach. Improving science education will not happen without the collaboration of educators and scientists working in a coordinated manner and it requires a long-term, continuous effort. To contribute effectively to K-12 education all scientists should refer to the National Science Education Standards, a set of policies that guide the development of curriculum and assessment. Ocean scientists can also specifically refer to the COSEE recommendations (www.cosee.org) that led to the creation of seven regional Centers for Ocean Sciences Education Excellence. Scientists can get involved in K-12 education in a multitude of ways. They should select projects that will accommodate time away from their research and teaching obligations, their talent, and their interest but also contribute to the education reform. A few examples of effective involvement are: 1) collaborating with colleagues in a school of education that can lead to better education of all students and future teachers, 2) acting as a resource for a national program or a local science fair, 3) serving on the advisory board of a program that develops educational material, 4) speaking out at professional meetings about the value of scientists' involvement in education, 5) speaking enthusiastically about the teaching profession. Improving science education in addition to research can seem a large, overwhelming task for scientists. As a result, focusing on projects that will fit the scientist's needs as well as benefit the science reform is of prime importance. It takes an enormous amount of work and financial and personnel resources to start a new program with measurable impact on students. So, finding the right opportunity is a priority, and stepping-in pre-existing programs to contribute right away without having to re-invent the wheel is a good approach. Education and outreach sessions are expanding at professional, scientific meetings such as AGU, and provide an excellent start for those in search of new educational experiences. Contacting a regional COSEE is also a very effective way to get involved.

Get Involved in Education and Public Outreach! The Science Mission Directorate Science E/PO Forums Are Here to Help

NASA Astrophysics Data System (ADS)

Shipp, S. S.; Buxner, S.; Schwerin, T. G.; Hsu, B. C.; Peticolas, L. M.; Smith, D.; Meinke, B. K.

2013-12-01

NASA's Science Mission Directorate (SMD) Education and Public Outreach (E/PO) Forums help to engage, extend, support, and coordinate the efforts of the community of E/PO professionals and scientists involved in Earth and space science education activities. This work is undertaken to maximize the effectiveness and efficiency of the overall national NASA science education and outreach effort made up of individual efforts run by these education professionals. This includes facilitating scientist engagement in education and outreach. The Forums have been developing toolkits and pathways to support planetary, Earth, astrophysics, and heliophysics scientists who are - or who are interested in becoming - involved in E/PO. These tools include: 1) Pathways to learn about SMD and E/PO community announcements and opportunities, share news about E/PO programs, let the E/PO community know you are interested in becoming involved, and discover education programs needing scientist input and/or support. These pathways include weekly e-news, the SMD E/PO online community workspace, monthly community calls, conferences and meetings of opportunity. 2) Portals to help you find out what education resources already exist, obtain resources to share with students of all levels - from K-12 to graduate students, - and disseminate your materials. These include E/PO samplers and toolkits (sampling of resources selected for scientists who work with students, teachers, and the public), the one-stop shop of reviewed resources from the NASA Earth and space science education portfolio NASAWavelength.org, and the online clearinghouse of Earth and space science higher education materials EarthSpace (http://www.lpi.usra.edu/earthspace). 3) Connections to education specialists who can help you design and implement meaningful E/PO programs - small to large. Education specialists can help you understand what research says about how people learn and effective practices for achieving your goals, place your programs in context (e.g., Beyond IYA, Sun-Earth Day, launch events, 50 Years of Solar System Exploration, Earth Science Week), and get your programs and products disseminated. 4) Connections to education professionals to collaborate with you on educational programs, involve intended audience members as partners to guide your programs, reach a broader audience, and insure impact with external partners through the E/PO community contact database and workspace profiles, conferences, meetings, and SMD E/PO community annual retreats. Recently developed, the NASA SMD Scientist Speaker's Bureau (http://www.lpi.usra.edu/education/speaker) offers an online portal to connect scientists interested in getting involved in E/PO projects - giving public talks, classroom visits, and virtual connections - with audiences. Learn more about the Forums and the opportunities to become involved in E/PO and to share your science with students, educators, and the general public at http://smdepo.org.

Bringing Space Scientists, Teachers, and Students Together With The CINDI E/PO Program

NASA Astrophysics Data System (ADS)

Urquhart, M.; Hairston, M.

2007-12-01

We will report on the activities, challenges, and successes of the ongoing collaboration between the William B. Hanson Center for Space Sciences (CSS) and the Department of Science/Mathematics Education (SME) at the University of Texas at Dallas. At the core of our partnership is the Education and Public Outreach program for the Coupled Ion / Neutral Dynamics Investigation (CINDI) instrument. CINDI is a NASA-funded program on the Air Force's Communication / Navigation Outage Forecast Satellite (C/NOFS) which will be launched in summer 2008. The CSS faculty and research scientists and the SME faculty and students have created a dynamic program that brings scientists and K-12 teachers together. Our activities include middle and high school curriculum development, teachers workshops, graduate course work for teachers, creation of the popular "Cindi in Space" educational comic book, and bringing K-12 teachers and students to work and/or visit with the CINDI scientists. We will present the outcomes of this collaborative effort as well as our recent experience of having a physics teacher from a local high school as our Teacher in Residence at CSS in summer 2007.

Canopy in the Clouds: Integrating Science and Media to Inspire a New Generation of Scientists

NASA Astrophysics Data System (ADS)

Goldsmith, G. R.; Fulton, A. D.; Witherill, C. D.

2008-12-01

Innovative approaches to science education are critical for inspiring a new generation of scientists. In a world where students are inundated with digital media inviting them to explore exciting, emerging disciplines, science often lags behind in using progressive media techniques. Additionally, science education media often neglects to include the scientists conducting research, thereby disconnecting students from the excitement, adventure, and beauty of conducting research in the field. Here we present initial work from a science education media project entitled Canopy in the Clouds. In particular, we address the goals and approach of the project, the logistics associated with generating educational material at a foreign field site, and the challenges associated with effectively integrating science and media. Canopy in the Clouds is designed to engage students in research, motivate a new generation of young scientists, and promote conservation from the perspective of a current research project being conducted in the canopy of a tropical montane cloud forest located in Monteverde, Costa Rica. The project seeks to generate curriculum based on multiple, immersive forms of novel digital media that attract and maintain student attention. By doing so from the perspective of an adventurous research project in a beautiful and highly biodiverse region, we hope to engage students in science and enhance bioliteracy. However, there are considerable logistic considerations associated with such an approach, including safety, travel, permitting, and equipment maintenance. Additionally, the goals of both the scientific research and the educational media project must be balanced in order to meet objectives in a timely fashion. Finally, materials generated in the field must be translated to viable final products and distributed. Work associated with Canopy in the Clouds will thus provide insight into this process and can serve to inform future science education and outreach efforts.

Opportunities for IPY Higher Education and Outreach

NASA Astrophysics Data System (ADS)

Sparrow, E. B.

2007-12-01

A very rich network for higher education and outreach during the fourth International Polar Year (IPY) exists through the University of the Arctic (UArctic, www.uarctic.org), a collaborative consortium of more than ninety institutions e.g. universities, colleges, and other organizations committed to higher education and research in the North, as well as eighteen other projects submitted as Expression of Intents to the IPY Joint Committee formed into an IPY cluster. The coordination office for this UArctic IPY education outreach efforts is located at the University of Alaska Fairbanks (www.uaf.edu and www.alaska.edu/ipy). The education outreach programs reflect a continuum of learning as a lifelong process that targets different audiences and approaches: 1) primary and secondary students through teacher professional development workshops on science teaching and research; 2) undergraduate students via education and research experience; 3) graduate students through integrated education and research; 4) early career scientists/university faculty via professional development; and 5) communities/ general public via continuing education/adult education either through formal or informal ways. Additionally there are organizations such as the Association of Polar Early Career Scientists (APECS) and the Youth Steering Committee (YSC) including a newly formed group on tertiary education to nurture the next generation of polar and non-polar scientists and foster the leadership of the next IPY.

From professional lives to inclusive practice: Science teachers and scientists' views of gender and ethnicity in science education

NASA Astrophysics Data System (ADS)

Bianchini, Julie A.; Cavazos, Lynnette M.; Helms, Jenifer V.

2000-08-01

To provide insight into issues of gender and ethnicity in science education, we examine the views of approximately 60 secondary science teachers and university scientists from three different research projects. In each project, participants and researcher explored the intersection of professional and personal identities; views of the nature of science; beliefs related to students' experiences in science education; and kinds of curricular and instructional strategies used to promote access and equity for all students. Participants' interviews were analyzed qualitatively for patterns across these four dimensions of inclusive science education. Analysis of data revealed a wide range of beliefs and experiences along each dimension. From our findings, we argue for careful examination of the ways identities shape instructors' professional experiences and educational practices; critical, constructive conversations about feminist science studies scholarship between professional developers and science teachers or scientists; and reasoned reflection on how views of students can inform recommendations for inclusive content and instruction. We conclude with the call for increased sophistication in the conceptualization and implementation of solutions to the problem of women and ethnic minorities in science education, for balancing recognition of systematic gender and ethnic bias with sensitivity to instructors and students' diverse interests and experiences.

Infrared astronomy in science and education

NASA Astrophysics Data System (ADS)

Mayeur, Paul Anthony

This dissertation looks at the effects of an educator-scientist partnership on the creation of an inquiry based science lesson for the middle school classroom. The lesson was initially created by a scientist following their science research, but changed as the scientist began working with teachers. The changes in the lesson show that scientists and educators may not agree on what is considered appropriate for a science lesson because of time commitment and grade level. However, by working together the partnership is able to reach a compromise of the lesson that allows for the students to get the best possible outcome. This dissertation also shows that science research is a method of inquiry, which can be brought to the classroom through inquiry education. The science research the lesson followed looks at the interstellar dust cloud DC 314.8-5.1, which is unique because of the cloud's proximity to a B-type star with no known association. This thesis did a survey of the area looking for background sources that can be used for future spectroscopical studies. Further, the survey led to the discovery of two possible young stellar objects. In order to fuel educator-scientist interaction and to bring inquiry education into the middle school classroom a scientist created a web-based science lesson that incorporated real NASA data into the middle-school classroom. This lesson was based on the scientist's research in infrared astronomy within the broader context of astrobiology. The lesson includes students plotting real data; in the process the students learn about infrared radiation, star color, and the wavelength/temperature relationship. These are all topics that were studied in the scientist's research, which led the scientist to the idea of creating a lesson for the middle-school classroom. This lesson is based on the principles of inquiry-based learning. Inquiry lessons can bring together these ideas into one place and hopefully inspire new generations to explore the world and universe through science. The scientist then worked with five teachers to edit the lesson for each teacher's classroom. For four of five teachers the lesson changed from an online based lesson that used Excel to a PowerPoint presentation and paper graphing. It is shown here that partnerships between scientists and educators are beneficial for both parties as it allows scientists to understand how to communicate their scientific findings to the general public, while allowing teachers to stay updated with the most advanced science research.

Survey of K-12 Science Teachers' Educational Product Needs from Planetary Scientists

ERIC Educational Resources Information Center

Slater, Stephanie J.; Slater, Timothy F.; Olsen, Julia K.

2009-01-01

Most education reform documents of the last two decades call for students to have authentic science inquiry experiences that mimic scientific research using real scientific data. In order for professional planetary scientists to provide the most useful data and professional development for K-12 teachers in support of science education reform, an…

Bringing 3D Printing to Geophysical Science Education

NASA Astrophysics Data System (ADS)

Boghosian, A.; Turrin, M.; Porter, D. F.

2014-12-01

3D printing technology has been embraced by many technical fields, and is rapidly making its way into peoples' homes and schools. While there is a growing educational and hobbyist community engaged in the STEM focused technical and intellectual challenges associated with 3D printing, there is unrealized potential for the earth science community to use 3D printing to communicate scientific research to the public. Moreover, 3D printing offers scientists the opportunity to connect students and the public with novel visualizations of real data. As opposed to introducing terrestrial measurements through the use of colormaps and gradients, scientists can represent 3D concepts with 3D models, offering a more intuitive education tool. Furthermore, the tactile aspect of models make geophysical concepts accessible to a wide range of learning styles like kinesthetic or tactile, and learners including both visually impaired and color-blind students.We present a workflow whereby scientists, students, and the general public will be able to 3D print their own versions of geophysical datasets, even adding time through layering to include a 4th dimension, for a "4D" print. This will enable scientists with unique and expert insights into the data to easily create the tools they need to communicate their research. It will allow educators to quickly produce teaching aids for their students. Most importantly, it will enable the students themselves to translate the 2D representation of geophysical data into a 3D representation of that same data, reinforcing spatial reasoning.

WATERS - Integrating Science and Education Through the Development of an Education & Outreach Program that Engages Scientists, Students and Citizens

NASA Astrophysics Data System (ADS)

Eschenbach, E. A.; Conklin, M. H.

2007-12-01

The need to train students in hydrologic science and environmental engineering is well established. Likewise, the public requires a raised awareness of the seriousness of water quality and availability problems. The WATERS Network (WATer and Environmental Research Systems Network ) has the potential to significantly change the way students, researchers, citizens, policy makers and industry members learn about environmental problems and solutions regarding water quality, quantity and distribution. This potential can be met if the efforts of water scientists, computer scientists, and educators are integrated appropriately. Successful pilot projects have found that cyberinfrastructure for education and outreach needs to be developed in parallel with research related cyberinfrastructure. We propose further integration of research, education and outreach activities. Through the use of technology that connects students, faculty, researchers, policy makers and others, WATERS Network can provide learning opportunities and teaching efficiencies that can revolutionize environmental science and engineering education. However, there are a plethora of existing environmental science and engineering educational programs. In this environment, WATERS can make a greater impact through careful selection of activities that build upon its unique strengths, that have high potential for engaging the members, and that meet identified needs: (i) modernizing curricula and pedagogy (ii) integrating science and education, (iii) sustainable professional development, and (iv) training the next generation of interdisciplinary water and social scientists and environmental engineers. National and observatory-based education facilities would establish the physical infrastructure necessary to coordinate education and outreach activities. Each observatory would partner with local educators and citizens to develop activities congruent with the scientific mission of the observatory. An unprecedented opportunity exists for educational research of both formal and informal environmental science and engineering education in order to understand how the Network can be efficiently used to create effective technology-based learning environments for all participants.

Becoming a scientist: A qualitative study of the educational experience of undergraduates working in an American and a Brazilian research laboratory

NASA Astrophysics Data System (ADS)

Pascoa, Maria Beatriz Amorim

Because the production of scientific and technological innovations has been at the center of debates for economic growth, scientists are recognized as important actors in the current global market. In this study, I will examine the undergraduate education of future scientists by focusing on students working in research projects of faculty members. This research activity has been promoted by American and Brazilian public agencies as an attempt to attract more college students to scientific careers as well as to improve their future performance in science. Evaluations of these programs have focused on important quantitative indicators focusing mainly on the amount of students that later choose to pursue scientific careers. However, these studies fail to address important educational aspects of undergraduates' experience. In this research, I explore the educational processes taking place as students are introduced to the making of science in order to understand how and what they are learning. Three bodies of literature illuminates the formulation and the analysis of the research questions: (1) theories of globalization situate the education of scientists within the dynamics of a broader social, economic, cultural, and historical framework; (2) the critical pedagogy of Paulo Freire is the basis for the understanding of the pedagogical processes shaping undergraduate students' experiences within the research site; (3) Critical and Cultural Studies of Science and Technology illuminate the analysis of the complex interactions and practices constructed within the laboratory. In order to understand the educational processes shaping the experiences of undergraduate students engaged in research activities, I conducted a qualitative investigation based on participant-observation and in-depth interviews in an American and a Brazilian laboratories. The two sites constituted insightful case studies that illuminated the understanding of inquires about the training of students in science. In addition, the study of two countries enriched the research inquiry, adding to the findings reflections on the ways differences in national contexts affects scientific training and scientific practices. Mainly, this qualitative research of students in laboratories offers some concrete recommendations and illuminating reflections for science educators, science policy makers, and for those working in the understanding of science epistemologies.

Graduate students in oceanography: Recruitment, success, and career prospects

NASA Astrophysics Data System (ADS)

Nowell, Arthur R. M.; Hollister, Charles D.

Graduate education, student quality, stipend support, and subsequent employment form a triad of concern to many oceanographers. While the number of graduate degree programs in oceanography in the U.S. exceeds 50, remarkably few data are available on numbers of student applications, student survival rates, the quality of the applicants and accepted students, and their subsequent employment.Consequently, most discussions within an institution are based on data from a single school, while most statements made to federal government program managers by scientists are based on personal perceptions and feelings. With the emerging global initiatives, which are very labor intensive, it appears appropriate to ask, “Is there an impending crisis in graduate education in oceanography?” Widespread concern about availability of new talent, the quality of incoming students, and the overall national crisis in science and engineering student recruitment has led many scientists to state that oceanography has widespread problems in terms of student numbers and, more importantly, quality. Often, when a scientist does not find a student in the spring application rites, the scientist declares there is a national shortage of well-qualified students. Moreover, in certain subdisciplines of the field (e.g., physical oceanography) the crisis is perceived as severe and immediate, though as we shall see, physical oceanography is in an improving mode and is also experiencing an interesting increase in the numbers of well-qualified women applicants.

Engaging with science: High school students in summer lab internships

NASA Astrophysics Data System (ADS)

Bequette, Marjorie Bullitt

Years of research and rhetoric have suggested that students should be given the opportunity to work with practicing scientists as a way to develop more sophisticated ideas about the nature of science, yet little research about these experiences exists. This project uses a case study approach to examine the experience of eight high school students working part-time during one summer as research assistants in biomedical laboratories. The students completed small research studies under the supervision of scientist-mentors. This dissertation explores questions related to how these students learned to work in a lab, in what ways they grew to understand this scientific context, and how their own relationships with science changed. The goal of looking at these young adults' summer experiences in science labs is to make suggestions for three settings: programs like this one, where high school students work closely with scientists in lab settings; other programs where scientists and students work together; and science education more generally. Analysis of pre- and post-interviews with students, and extensive observations of their laboratory work, suggests that students develop new ideas about the culture of science and the day-to-day workings of the labs. These ideas hold potential power for the students, and other participants in both similar and different educational settings, as they prepare for lives as scientifically engaged adults.

Science Cafes: Engaging graduate students one drink at a time!

NASA Astrophysics Data System (ADS)

Schiebel, H.; Chen, R. F.

2016-02-01

Science Cafes are events that take place in casual settings (pubs, coffeehouses) that are typically open to a broad audience and feature engaging conversations with scientists about particular topics. Science Cafes are a grassroots movement and exist on an international scale with a common goal of engaging broad audiences in informal scientific discussions. Graduate Students for Ocean Education (GrOE), funded by COSEE OCEAN (Center for Ocean Science Education Excellence—Ocean Communities in Science Education And social Networks), has taken this model and honed in on a specific audience: graduate students. Through monthly Science Cafes with varying themes (ocean acidification to remote sensing), GrOE has engaged over two hundred graduate students throughout New England. While attendance at the Science Cafes is consistent, the presence and engagement of graduate students on the GrOE Facebook page is now growing, a trend attributed to having face-to-face contact with scientists and other graduate students.

"What's A Geoscientist Do?": A Student Recruitment And Education Tool

NASA Astrophysics Data System (ADS)

Hughes, C. G.

2015-12-01

Student perception of science, particularly the earth sciences, is not based on actual science jobs. Students have difficulty envisioning themselves as scientists, or in understanding the role of science in their lives as a result. Not all students can envision themselves as scientists when first enrolling in college. While student recruitment into geoscience programs starts before college enrollment at many universities, general education science requirements can act as a gateway into these majors as well. By providing students in general education science classes with more accurate insights into the scientific process and what it means to be a scientist, these classes can help students envision themselves as scientists. A short module, to be embedded within lectures, has been developed to improve recruitment from Clarion University's Introductory Earth Science classes entitled "What's A Geoscientist Do?". As this module aims to help students visualize themselves as geoscientists through examples, diversity of the examples is critical to recruiting students from underrepresented groups. Images and subjects within these modules are carefully selected to emphasize the fact that the geosciences are not, and should not be, the exclusive province of the stereotypical older, white, male scientist. Noteworthy individuals (e.g. John Wesley Powell, Roger Arliner Young) may be highlighted, or the discussion may focus on a particular career path (e.g. hydrologist) relevant to that day's material. While some students are initially attracted to the geosciences due to a love of the outdoors, many students have never spent a night outdoors, and do not find this aspect of the geosciences particularly appealing. "What's A Geoscientist Do?" has been designed to expose these students to the breadth of the field, including a number of geoscience jobs focused on laboratory (e.g. geochemistry) or computer (e.g. GIS, remote sensing, scientific illustration) work instead of focusing exclusively on fieldwork. As Clarion University students tend to be very job-oriented, information on careers includes average starting salaries with the hope of improving student's opinions of the position as possible future employment - helping students (and their families) realize they can support themselves in a geoscience career.

Identity Matching to Scientists: Differences That Make a Difference?

ERIC Educational Resources Information Center

Andersen, Hanne Moeller; Krogh, Lars Brian; Lykkegaard, Eva

2014-01-01

Students' images of science and scientists are generally assumed to influence their related subject choices and aspirations for tertiary education within science and technology. Several research studies have shown that many young people hold rather stereotypical images of scientists, making it hard for them to see themselves as future scientists.…

Seafloor Eruptions Offer a Teachable Moment to Help SEAS Students Understand Important Geological and Ecological Processes

NASA Astrophysics Data System (ADS)

Goehring, L.; Williams, C. S.

2006-12-01

In education parlance, a teachable moment is an opportunity that arises when students are engaged and primed to learn, typically in response to some memorable event. Earthquakes, volcanic eruptions, even natural disasters, if meaningful to the student, often serve to catalyze intense learning. Recent eruptions at the East Pacific Rise offer a potential teachable moment for students and teachers involved with SEAS, a Ridge 2000 education outreach program. SEAS uses a combination of web-facilitated and teacher-directed activities to make the remote deep-sea environment and the process of science relevant and meaningful. SEAS is a web-based, inquiry-oriented education program for middle and high school students. It features the science associated with Ridge 2000 research. Since 2003, SEAS has focused on the integrated study site at the East Pacific Rise (EPR) to help students understand geological and ecological processes at mid-ocean ridges and hydrothermal vents. SEAS students study EPR bathymetry maps, images of lava formations, photomosaics of diffuse flow communities, succession in the Bio-Geo Transect, as well as current research conducted during spring cruises. In the Classroom to Sea Lab, students make direct comparisons between shallow-water mussels and vent mussels (from the EPR) to understand differences in feeding strategies. The recent eruptions and loss of seafloor fauna at this site offer the Ridge 2000 program the opportunity to help students better understand the ephemeral and episodic nature of ridge environments, as well as the realities and processes of science (particularly field science). In January 2007, the SEAS program will again sail with a Ridge 2000 research team, and will work with scientists to report findings through the SEAS website. The eruptions at the EPR covered much of the study site, and scientists' instruments and experiments, in fresh lava. We intend to highlight the recency and effect of the eruptions, using the students' anticipated response as a motivator to deepen their understanding of the environment. SEAS depends on the contributions of many scientists within the Ridge 2000 community, and serves as an outreach channel for the whole community. Scientists can help field student questions during the Ask-a- Scientist email forum, serve as Report Reviewers, be featured in Scientist Spotlights, and help develop new Classroom to Sea labs and curricular materials. In the next four years, SEAS will integrate with the international GLOBE education program (www.globe.gov), and help our community reach even more students and teachers, worldwide.

Bringing Society to a Changing Polar Ocean: Polar Interdisciplinary Coordinated Education (ICE)

NASA Astrophysics Data System (ADS)

Schofield, O.

2015-12-01

Environmental changes in the Arctic and Antarctic appear to be accelerating and scientists are trying to understand both the patterns and the impacts of change. These changes will have profound impact on humanity and create a need for public education about these critical habitats. We have focused on a two-pronged strategy to increase public awareness as well as enable educators to discuss comfortably the implications of climate change. Our first focus is on entraining public support through the development of science documentaries about the science and people who conduct it. Antarctic Edge is a feature length award-winning documentary about climate change that has been released in May 2015 and has garnered interest in movie theatres and on social media stores (NetFlix, ITunes). This broad outreach is coupled with our group's interest assisting educators formally. The majority of current polar education is focused on direct educator engagement through personal research experiences that have impact on the participating educators' classrooms. Polar Interdisciplinary Coordinated Education (ICE) proposes to improve educator and student engagement in polar sciences through exposure to scientists and polar data. Through professional development and the creation of data tools, Polar ICE will reduce the logistical costs of bringing polar science to students in grades 6-16. We will provide opportunities to: 1) build capacity of polar scientists in communicating and engaging with diverse audiences; 2) create scalable, in-person and virtual opportunities for educators and students to engage with polar scientists and their research through data visualizations, data activities, educator workshops, webinars, and student research symposia; and 3) evaluate the outcomes of Polar ICE and contribute to our understanding of science education practices. We will use a blended learning approach to promote partnerships and cross-disciplinary sharing. This combined multi-pronged approach is critically important to entraining society in understanding the ramifications of changing polar systems.

Using Long-Distance Scientist Involvement to Enhance NASA Volunteer Network Educational Activities

NASA Astrophysics Data System (ADS)

Ferrari, K.

2012-12-01

Since 1999, the NASA/JPL Solar System Ambassadors (SSA) and Solar System Educators (SSEP) programs have used specially-trained volunteers to expand education and public outreach beyond the immediate NASA center regions. Integrating nationwide volunteers in these highly effective programs has helped optimize agency funding set aside for education. Since these volunteers were trained by NASA scientists and engineers, they acted as "stand-ins" for the mission team members in communities across the country. Through the efforts of these enthusiastic volunteers, students gained an increased awareness of NASA's space exploration missions through Solar System Ambassador classroom visits, and teachers across the country became familiarized with NASA's STEM (Science, Technology, Engineering and Mathematics) educational materials through Solar System Educator workshops; however the scientist was still distant. In 2003, NASA started the Digital Learning Network (DLN) to bring scientists into the classroom via videoconferencing. The first equipment was expensive and only schools that could afford the expenditure were able to benefit; however, recent advancements in software allow classrooms to connect to the DLN via personal computers and an internet connection. Through collaboration with the DLN at NASA's Jet Propulsion Laboratory and the Goddard Spaceflight Center, Solar System Ambassadors and Solar System Educators in remote parts of the country are able to bring scientists into their classroom visits or workshops as guest speakers. The goals of this collaboration are to provide special elements to the volunteers' event, allow scientists opportunities for education involvement with minimal effort, acquaint teachers with DLN services and enrich student's classroom learning experience.;

Should Scientists Be Involved in Teaching Science Writing and If So, How?

ERIC Educational Resources Information Center

Goodell, Rae

Realizing the importance of writing skills in communicating with other professionals and in educating the public, scientists and scientific institutions have renewed their interest in the writing education of science students. Informal surveys show that technological and engineering schools are reinstituting writing requirements and staffing the…

SOFIA Education and Public Outreach (EPO): Scientist/Educator Partnerships at 41,000 Feet

NASA Astrophysics Data System (ADS)

Backman, D.; Devore, E.; Bennett, M.

2003-12-01

NASA's Stratospheric Observatory for Infrared Astronomy (SOFIA) represents a unique opportunity for education and public outreach (EPO). SOFIA is the first research observatory -- airborne or ground-based -- in which close participation by educators and journalists is being designed into both the physical facility and the administrative structure of the observatory. With the overall goal of contributing to the public's awareness and understanding of science in general and astronomy in particular, the SOFIA EPO program will include formal K-12 and undergraduate educational activities, informal education, public outreach, and media relations. One of the most exciting and unique aspects of the SOFIA EPO program is the observatory's ability to carry up to 10 educators on science flights, enabling those educators to partner with scientists and participate in real research. Some 200 formal and informal educators per year are expected to participate in the SOFIA Airborne Astronomy Ambassadors program once full-scale operation is achieved. Educators who have participated in the Airborne Astronomy Ambassadors program will be encouraged to continue their scientific partnerships and will be supported in their efforts to carry new-found knowledge and enthusiasm to their students, other educators in their communities and the general public. The Airborne Astronomy Ambassadors will be supported as a national network via continued communications and material support from the SOFIA EPO program office, and will constitute a wide-spread outreach cadre for NASA and space sciences based on their experiences with airborne astronomy. Scientists, engineers, and other members of the SOFIA team will be encouraged to partner with local teachers and visit their classrooms as a part of the SOFIA Education Partners Program. Training for scientist-educators will be offered via the Astronomical Society of the Pacific's Project ASTRO network of astronomy education sites around the USA. This program will enable students to interact with scientists and other professionals on a one-to-one basis. Participating educators may fly onboard SOFIA with their scientist partners. Scientists who participate in this program will be able to work with educators and students in their local communities to forge long-lasting science education partnerships. The SOFIA EPO staff is interested in forming collaborations with interested organizations, other NASA missions, and individual astronomers. SOFIA is being developed and will be operated for NASA by USRA. The EPO program is being developed and will be operated jointly by the SETI Institute and the Astronomical Society of the Pacific.

Tides, Krill, Penguins, Oh My!: Scientists and Teachers Partner in Project CONVERGE to Bring Collaborative Antarctic Research, Authentic Data, and Scientific Inquiry into the Hands of NJ and NY Students

NASA Astrophysics Data System (ADS)

Hunter-thomson, K. I.; Kohut, J. T.; Florio, K.; McDonnell, J. D.; Ferraro, C.; Clark, H.; Gardner, K.; Oliver, M. J.

2016-02-01

How do you get middle and high school students excited about scientific inquiry? Have them join a collaborative research team in Antarctica! A comprehensive education program brought ocean science, marine ecology, and climate change impact research to more than 950 students in 2014-15 to increase their exposure to and excitement of current research. The program was integrated into a collaborative research project, involving five universities, that worked to characterize the connection between ocean circulation, plankton distribution, penguin foraging behavior, and climate change around Palmer Station, Antarctica. The scientists and education team co-led a weeklong workshop to expose 22 teachers to the research science, build relationships among the teachers and scientists, and refine the program to most effectively communicate the research to their students. In the fall, teachers taught NGSS-aligned, hands-on, data-focused classroom lessons to provide their students the necessary content to understand the project hypotheses using multiple science practices. Through a professional science blog and live video calls from Antarctica, students followed and discussed the science teams work while they were in the field. To apply the science practices the students had learned about, they designed, conducted, and analyzed their own ocean-related, inquiry-based research investigation as the culminating component of the program (results were presented at a Student Research Symposium attended by the science team). Of their own choosing, roughly half of the students used raw data from the CONVERGE research (including krill, CODAR, penguin, and glider data) for their investigations. This presentation will focus on the evaluation results of the education program to identify the aspects that successfully engaged teachers and students with scientific inquiry, science practices, and authentic data as well as the replicability of this integrated scientist-teacher partnership and education program.

Science Educational Outreach Programs That Benefit Students and Scientists

PubMed Central

Enyeart, Peter; Gracia, Brant; Wessel, Aimee; Jarmoskaite, Inga; Polioudakis, Damon; Stuart, Yoel; Gonzalez, Tony; MacKrell, Al; Rodenbusch, Stacia; Stovall, Gwendolyn M.; Beckham, Josh T.; Montgomery, Michael; Tasneem, Tania; Jones, Jack; Simmons, Sarah; Roux, Stanley

2016-01-01

Both scientists and the public would benefit from improved communication of basic scientific research and from integrating scientists into education outreach, but opportunities to support these efforts are limited. We have developed two low-cost programs—"Present Your PhD Thesis to a 12-Year-Old" and "Shadow a Scientist”—that combine training in science communication with outreach to area middle schools. We assessed the outcomes of these programs and found a 2-fold benefit: scientists improve their communication skills by explaining basic science research to a general audience, and students' enthusiasm for science and their scientific knowledge are increased. Here we present details about both programs, along with our assessment of them, and discuss the feasibility of exporting these programs to other universities. PMID:26844991

Perceived barriers to physician-scientist careers among female undergraduate medical students at the College of Medicine - Alfaisal University: a Saudi Arabian perspective.

PubMed

Abu-Zaid, Ahmed; Altinawi, Basmah

2014-04-01

At present, only a negligible number of matriculating and graduating female medical students express interest in physician-scientist careers. The aim of this study is to explore the perceived barriers towards pursuing physician-scientist careers by female undergraduate medical students at College of Medicine - Alfaisal University, Saudi Arabia. An online, anonymous, self-rating survey was administered. The survey assessed students' perceived barriers towards potential physician-scientist careers by responding to typical 5-point Likert scale statements. One hundred sixteen students (116/171) participated in the survey with a 67.8% response rate. The top three barriers to such physician-scientist careers were greater preference towards patient care than research (75%), lack of conviction as regards merging a fruitful research profession with satisfying motherhood life (52.6%) and paucity of recognizing successful and well-known female physician-scientist role models in the country (48.3%). Our results showed that the perceived barriers to physician-scientist careers by College of Medicine - Alfaisal University's female undergraduate medical students were largely identical to the Western literature with few differences and more influence of cultural reasons. It is crucial for medical educators in Saudi Arabia to work on mechanisms that stimulate female students' interest in research and resolve all barriers that stand in the face of students towards considering physician-scientist careers.

Promoting Diversity Through Polar Interdisciplinary Coordinated Education (Polar ICE)

NASA Astrophysics Data System (ADS)

McDonnell, J. D.; Hotaling, L. A.; Garza, C.; Van Dyk, P. B.; Hunter-thomson, K. I.; Middendorf, J.; Daniel, A.; Matsumoto, G. I.; Schofield, O.

2017-12-01

Polar Interdisciplinary Coordinated Education (ICE) is an education and outreach program designed to provide public access to the Antarctic and Arctic regions through polar data and interactions with the scientists. The program provides multi-faceted science communication training for early career scientists that consist of a face-to face workshop and opportunities to apply these skills. The key components of the scientist training workshop include cultural competency training, deconstructing/decoding science for non-expert audiences, the art of telling science stories, and networking with members of the education and outreach community and reflecting on communication skills. Scientists partner with educators to provide professional development for K-12 educators and support for student research symposia. Polar ICE has initiated a Polar Literacy initiative that provides both a grounding in big ideas in polar science and science communication training designed to underscore the importance of the Polar Regions to the public while promoting interdisciplinary collaborations between scientists and educators. Our ultimate objective is to promote STEM identity through professional development of scientists and educators while developing career awareness of STEM pathways in Polar science.

Building place-based collaborations to develop high school students' groundwater systems knowledge and decision-making capacity

NASA Astrophysics Data System (ADS)

Podrasky, A.; Covitt, B. A.; Woessner, W.

2017-12-01

The availability of clean water to support human uses and ecological integrity has become an urgent interest for many scientists, decision makers and citizens. Likewise, as computational capabilities increasingly revolutionize and become integral to the practice of science, technology, engineering and math (STEM) disciplines, the STEM+ Computing (STEM+C) Partnerships program seeks to integrate the use of computational approaches in K-12 STEM teaching and learning. The Comp Hydro project, funded by a STEM+C grant from the National Science Foundation, brings together a diverse team of scientists, educators, professionals and citizens at sites in Arizona, Colorado, Maryland and Montana to foster water literacy, as well as computational science literacy, by integrating authentic, place- and data- based learning using physical, mathematical, computational and conceptual models. This multi-state project is currently engaging four teams of six teachers who work during two academic years with educators and scientists at each site. Teams work to develop instructional units specific to their region that integrate hydrologic science and computational modeling. The units, currently being piloted in high school earth and environmental science classes, provide a classroom context to investigate student understanding of how computation is used in Earth systems science. To develop effective science instruction that is rich in place- and data- based learning, effective collaborations between researchers, educators, scientists, professionals and citizens are crucial. In this poster, we focus on project implementation in Montana, where an instructional unit has been developed and is being tested through collaboration among University scientists, researchers and educators, high school teachers and agency and industry scientists and engineers. In particular, we discuss three characteristics of effective collaborative science education design for developing and implementing place- and data- based science education to support students in developing socio-scientific and computational literacy sufficient for making decisions about real world issues such as groundwater contamination. These characteristics include that science education experiences are real, responsive/accessible and rigorous.

Climate Research by K-12 Students: Can They Do It? Will Anybody Care?

NASA Astrophysics Data System (ADS)

Brooks, D. R.

2011-12-01

Starting from the premise that engaging students in authentic science research is an activity that benefits science education in general, it is first necessary to consider whether students, in collaboration with teachers and climate scientists, can do climate-related research that actually has scientific value. A workshop held in November 2010, co-sponsored by NSF and NOAA, addressed this question. It took as its starting point this "scientific interest" test: "If students conduct a climate-related research project according to protocols designed in collaboration with climate scientists, when they get done, will any of those scientists care whether they did it or not?" If the answer to this question is "yes," then the project may constitute authentic research, but if the answer is "no," then the project may have educational value, but it is not research. This test is important because only when climate scientists (and other stakeholders interested in climate and climate change) are invested in the outcomes of student research will meaningful student research programs with sustainable support be forthcoming. The absence of climate-related projects in high-level student science fair competitions indicates that, currently, the investment and infrastructure required to support student climate research is lacking. As a result, climate science is losing the battle for the "hearts and minds" of today's best students. The critical task for student climate research is to define projects that are theoretically and practically accessible. This excludes the "big questions" of climate science, such as "Is Earth getting warmer?", but includes many observationally based projects that can help to refine our understanding of climate and climate change. The characteristics of collaborative climate research with students include: 1. carefully drawn distinctions between inquiry-based "learning about" activities and actual research; 2. an identified audience of potential stakeholders who will care about the results of the research; 3. clearly defined expectations, logistics, and outcomes for all participants. Some examples of appropriate data-based research topics include: 1. monitoring black carbon, atmospheric aerosols, and water vapor; 2. pyranometry at sufficiently high temporal resolution to study cloud patterns; 3. urban heat island and other microclimate effects; 4. monitoring benthic habitats and seafloor temperatures; 5. monitoring free-floating ocean buoys to help in the establishment of mobile marine sanctuaries; 6. monitoring surface reflectivity to generate highly localized normalized difference vegetation indices; 7. tracking habitats for vector-borne disease carriers in developing countries. Both education and science communities need to work harder to support student climate research. Educational institutions must build authentic student research into their mission statements. Scientists need to be more aware of the constraints under which teachers and their students must operate on a day-to-day basis. But, students can participate in authentic climate research if educators and scientists expect them to do real research, are honest with them about what is required to do real research, and are willing to provide persistent ongoing support.

Opportunities for Scientists to Engage the Public & Inspire Students in Science

NASA Astrophysics Data System (ADS)

Vaughan, R. G.; Worssam, J.; Vaughan, A. F.

2014-12-01

Increasingly, research scientists are learning that communicating science to broad, non-specialist audiences, particularly students, is just as important as communicating science to their peers via peer-reviewed scientific publications. This presentation highlights opportunities that scientists in Flagstaff, AZ have to foster public support of science & inspire students to study STEM disciplines. The goal here is to share ideas, personal experiences, & the rewards, for both students & research professionals, of engaging in science education & public outreach. Flagstaff, AZ, "America's First STEM Community," has a uniquely rich community of organizations engaged in science & engineering research & innovation, including the Flagstaff Arboretum, Coconino Community College, Gore Industries, Lowell Observatory, Museum of Northern Arizona, National Weather Service, National Park Service, National Forest Service, Northern Arizona University, Northern Arizona Center for Entrepreneurship & Technology, US Geological Survey, US Naval Observatory, & Willow Bend Environmental Education Center. These organizations connect with the Northern Arizona community during the yearly Flagstaff Festival of Science - the third oldest science festival in the world - a 10 day long, free, science festival featuring daily public lectures, open houses, interactive science & technology exhibits, field trips, & in-school speaker programs. Many research scientists from these organizations participate in these activities, e.g., public lectures, open houses, & in-school speaker programs, & also volunteer as mentors for science & engineering themed clubs in local schools. An example of a novel, innovative program, developed by a local K-12 science teacher, is the "Scientists-in-the-Classroom" mentor program, which pairs all 7th & 8th grade students with a working research scientist for the entire school year. Led by the student & guided by the mentor, they develop a variety of science / technology projects, which the students then present at year's end. From the perspective of an active research scientist, such outreach activities take little time & effort (~ 0.05 FTE), but pay large dividends in the long run, in inciting public support for science & inspiring the next generation of scientists & engineers.

From Laboratories to Classrooms: Involving Scientists in Science Education

NASA Astrophysics Data System (ADS)

DeVore, E. K.

2001-12-01

Scientists play a key role in science education: the adventure of making new discoveries excites and motivates students. Yet, American science education test scores lag behind those of other industrial countries, and the call for better science, math and technology education is widespread. Thus, improving American science, math and technological literacy is a major educational goal for the NSF and NASA. Today, funding for research often carries a requirement that the scientist be actively involved in education and public outreach (E/PO) to enhance the science literacy of students, teachers and citizens. How can scientists contribute effectively to E/PO? What roles can scientists take in E/PO? And, how can this be balanced with research requirements and timelines? This talk will focus on these questions, with examples drawn from the author's projects that involve scientists in working with K-12 teacher professional development and with K-12 curriculum development and implementation. Experiences and strategies for teacher professional development in the research environment will be discussed in the context of NASA's airborne astronomy education and outreach projects: the Flight Opportunities for Science Teacher EnRichment project and the future Airborne Ambassadors Program for NASA's Stratospheric Observatory for Infrared Astronomy (SOFIA). Effective partnerships with scientists as content experts in the development of new classroom materials will be described with examples from the SETI Institute's Life in the Universe curriculum series for grades 3-9, and Voyages Through Time, an integrated high school science course. The author and the SETI Institute wish to acknowledge funding as well as scientific and technical support from the National Science Foundation, the National Aeronautics and Space Administration, the Hewlett Packard Company, the Foundation for Microbiology, and the Combined Federated Charities.

Investigation into Omani Secondary School Students' Perceptions of Scientists and Their Work

ERIC Educational Resources Information Center

Ambusaidi, Abdullah; Al-Muqeemi, Fatma; Al-Salmi, Maya

2015-01-01

The purpose of this study was to investigate Omani 12th grade students' perceptions about scientists and their work and accordingly propose some recommendations in order to encourage new generations to choose science and engineering-oriented specialisations in higher education. A 37-item questionnaire was designed to determine these perceptions…

Meta-analytic Evaluation of a Virtual Field Trip to Connect Middle School Students with University Scientists

NASA Astrophysics Data System (ADS)

Adedokun, Omolola A.; Liu, Jia; Parker, Loran Carleton; Burgess, Wilella

2015-02-01

Although virtual field trips are becoming popular, there are few empirical studies of their impacts on student outcomes. This study reports on a meta-analytic evaluation of the impact of a virtual field trip on student perceptions of scientists. Specifically, the study examined the summary effect of zipTrips broadcasts on evaluation participants' perceptions of scientists, as well as the moderating effect of program type on program impact. The results showed statistically significant effect of each broadcast, as well as statistically significant summary (combined) effect of zipTrips on evaluation participants' perceptions of scientists. Results of the moderation analysis showed that the effect was greater for the students that participated in the evaluation of the 8th grade broadcasts, providing additional insight into the role of program variation in predicting differential program impact. This study illustrates how meta-analysis, a methodology that should be of interest to STEM education researchers and evaluation practitioners, can be used to summarize the effects of multiple offerings of the same program. Other implications for STEM educators are discussed.

Science in action: An interdisciplinary science education program

NASA Technical Reports Server (NTRS)

Horton, Linda L.

1992-01-01

Science in Action is an education outreach program for pre-collegiate students. It is based on the concept that, in order to interest students in science, they must see science and scientists at work. The program encompasses the full range of scientific disciplines - the core sciences, engineering, and mathematics. A unique aspect of the program is the involvement and support of scientists and engineers representing local professional societies, industries, business, and academic institutions. An outline of the program is given.

NASA missions CALIPSO and CloudSat partner with the GLOBE program to provide student opportunities for data collection to aid scientists researching climate change

NASA Astrophysics Data System (ADS)

Robinson, D. Q.; Maggi, B. H.; Krumm, D. K.

2004-12-01

NASA places great emphasis on developing partnerships with education communities, including collaborations with university scientists, K-16 science educators and students. Two universities contributing to this effort through their involvement with NASA satellite based research missions, CALIPSO and CloudSat, are Hampton University and Colorado State University. Both universities provide atmospheric research scientists for the missions and leadership for the Education and Outreach Programs developed for CALIPSO and CloudSat. These satellite-based research missions are co-manifested for launch during the spring 2004 and are included in the Afternoon Constellation also known as the "A-Train" satellite formation. The A-Train will consist of six missions flying in close proximity, providing combined detailed observations about the Earth's atmosphere allowing scientists to make better predictions related to climate change. CloudSat will use radar and provide a global survey of cloud properties to aid with improving cloud models and the accuracy of weather forecasts. CALIPSO will use Lidar to detect size and distribution of aerosols that will aid in improving our understanding of the role aerosols and clouds play in Earth's climate system. Each of the A-Train missions has a unique education and outreach program for students and teachers. Included in the CALIPSO and CloudSat education and outreach is a partnership with the GLOBE Program. GLOBE involves students worldwide in data collection and mission observations. The GLOBE program is a network of K-14 schools, science centers, after school programs, and environmental clubs from over 105 countries. Students participating in GLOBE collect scientific data according to precise protocols and enter the data into a central database allowing both scientists and students to utilize the information collected. The CALIPSO and CloudSat partnership with GLOBE involves the enlistment of student assistance worldwide for data collection that will be used by both missions. Students use the existing GLOBE protocols on aerosols and clouds to collect data as the satellites pass over their schools. CloudSat scientists will involve students by having them report visual observations related to cloud cover, cloud type and precipitation. This information will be compared to the CloudSat radar data to determine the accuracy of the satellite radar unit. CALIPSO will have students collect and report on aerosol measurements taken with a handheld sun photometer. These measurements will then be compared to those taken with the lidar riding on the satellite. Climate change and the effects aerosols have on climate are current topics in schools today. It now appears likely that anthropogenic aerosols resulting from industrial activities and agricultural burning are affecting weather and climate in some regions of the world. The data collected by students internationally for CALIPSO and CloudSat will allow them to better understand the impacts made by humans on Earth's atmosphere and how these impacts are global in scope. In return, scientists gain a valuable resource giving them ground-based data in more locations than would be possible using established weather stations and research laboratories. The partnership established by the CALIPSO and CloudSat missions with the GLOBE program will provide an opportunity to enrich earth science education in schools with a sustainable connection to NASA education.

Aerospace scientists. We're tomorrow-minded people

NASA Technical Reports Server (NTRS)

Lewis, M. H.

1981-01-01

Brief job-related autobiographical sketches of scientists working on NASA space science projects are presented. Career and educational guidance is offered to students thinking about entering the space science field.

What can scientific practice look like in a classroom? Insights from scientists' critique of high school students' climate change argumentation practice

NASA Astrophysics Data System (ADS)

Walsh, E.; McGowan, V. C.

2015-12-01

The Next Generation Science Standards promote a vision in which learners engage in authentic knowledge in practice to tackle personally consequential science problems in the classroom. However, there is not yet a clear understanding amongst researchers and educators of what authentic practice looks like in a classroom and how this can be accomplished. This study explores these questions by examining interactions between scientists and students on a social media platform during two pilot enactments of a project-based curriculum focusing on the ecological impacts of climate change. During this unit, scientists provided feedback to students on infographics, visual representations of scientific information meant to communicate to an audience about climate change. We conceptualize the feedback and student work as boundary objects co-created by students and scientists moving between the school and scientific contexts, and analyze the structure and content of the scientists' feedback. We find that when giving feedback on a particular practice (e.g. argumentation), scientists would provide avenues, critiques and questions that incorporated many other practices (e.g. data analysis, visual communication); thus, scientists encouraged students to participate systemically in practices instead of isolating one particular practice. In addition, scientists drew attention to particular habits of mind that are valued in the scientific community and noted when students' work aligned with scientific values. In this way, scientists positioned students as capable of participating "scientifically." While traditionally, incorporating scientific inquiry in a classroom has emphasized student experimentation and data generation, in this work, we found that engaging with scientists around established scientific texts and data sets provided students with a platform for developing expertise in other important scientific practices during argment construction.

Student Planetary Investigators: A Program to Engage Students in Authentic Research Using NASA Mission Data

NASA Astrophysics Data System (ADS)

Hallau, K.; Turney, D.; Beisser, K.; Edmonds, J.; Grigsby, B.

2015-12-01

The Student Planetary Investigator (PI) Program engages students in authentic scientific research using NASA mission data. This student-focused STEM (Science, Technology, Engineering and Math) program combines problem-based learning modules, Next Generation Science Standards (NGSS) aligned curriculum, and live interactive webinars with mission scientists to create authentic research opportunities and career-ready experiences that prepare and inspire students to pursue STEM occupations. Primarily for high school students, the program employs distance-learning technologies to stream live presentations from mission scientists, archive those presentations to accommodate varied schedules, and collaborate with other student teams and scientists. Like its predecessor, the Mars Exploration Student Data Team (MESDT) program, the Student PI is free and open to teams across the country. To date, students have drafted research-based reports using data from the Lunar Reconnaissance Orbiter Mini-RF instrument and the MESSENGER Mercury orbiter, with plans to offer similar programs aligned with additional NASA missions in the future pending available funding. Overall, the program has reached about 600 students and their educators. Assessments based on qualitative and quantitative data gathered for each Student PI program have shown that students gain new understanding about the scientific process used by real-world scientists as well as gaining enthusiasm for STEM. Additionally, it is highly adaptable to other disciplines and fields. The Student PI program was created by the Johns Hopkins University Applied Physics Laboratory (APL) Space Department Education and Public Outreach office with support from NASA mission and instrument science and engineering teams.

ERESE Professional Development in Science Education: A collaboration of scientists, teachers, and information technologists

NASA Astrophysics Data System (ADS)

Staudigel, H.; Helly, M.; Massel Symons, C.; Koppers, A.; Helly, J.; Miller, S.

2005-12-01

The Enduring Resources in Earth Science Education (ERESE) project promotes inquiry based teaching of plate tectonics through professional development and distribution of digital library objects in the National Science Digital Library network. The overall ERESE goal is to bridge the gap between the scientists and educators, and our experience has shown that much can be gained by establishing a close collaboration between all parties involved in earth science education, from high school student to teacher -educator, and scientist. These collaborations yield substantial gains in terms of effective educational approaches, contents selection, and to produce an authentic class room research experience. ERESE professional development workshops promote a model of inquiry-based teaching that keeps the educator as far in the background as possible, while empowering the student to carry out a maximally independent inquiry. Key components in this process are: (1) use of a well selected provocative phenomenon to promote student's curiosity and to start the inquiry process, (2) care in the student guidance towards selection and formulation of a researchable question, (3) the involvement of teachers and scientists, in a close collaboration (4) teaching resource development with a strong feed-back from professional development workshops and classroom practice, (5) integration of science inquiry resources on all expert levels providing an environment that allows continuous access to science information from the most basic to the full scale science level. We expanded ERESE resource development into a volcanology field class on Hawaii to produce a website and digital library contents including field reports, exercises and images and field data. We further expanded our resource development through the participation of three high school students in a three-week seagoing expedition to the Samoan Archipelago. The high school seniors maintained a live expedition website and they participated in all science activities. Their work impacted ERESE by the development of digital resources, and introducing peer - mentoring into the inquiry process.

Using morphological awareness instruction to improve written language skills.

PubMed

Apel, Kenn; Werfel, Krystal

2014-10-01

Written English is a morphophonemic language. Researchers have documented that a conscious awareness of the morphological structure of English morphology is predictive of students' written language skills and that morphological awareness instruction leads to improvements in morphological awareness and in other written language skills. The purpose of this tutorial is to provide specific information to clinical scientists and other educators for integrating morphological awareness instruction into their written language instruction. The authors first define morphological awareness and provide an overview of the research on the effects of morphological awareness intervention on improving morphological awareness and written language skills. Measures used to assess morphological awareness ability are then discussed, followed by suggestions for how clinical scientists and other educators can provide morphological awareness instruction to improve the written language skills of the students they serve. By integrating morphological awareness instruction into the services they provide, clinical scientists and other educators will be providing their students with a strong tool to aid written language skills.

Making Social Scientists, or Not?: Glimpses of the Unmentionable in Doctoral Education

ERIC Educational Resources Information Center

Mills, David; Paulson, Julia

2014-01-01

Recent research on doctoral education in the U.K. has revealed the increasing number and diversity of academic relationships that shape the lives of research students, and students' own role in activating, mobilising and maintaining these relationships. Higher education policy reforms promoting doctoral "skills training",…

How high school science-related experiences influenced science career persistence

NASA Astrophysics Data System (ADS)

Shaw, Andrew D.

The events of 9/11 brought into focus two ongoing trends that were present before this tragedy and have continued since: (1) The United States needs more scientists if it is to ensure its freedoms and maintain its economy. (2) The number of scientists in the "pipeline" is declining because of the diminished presence of foreign scientists (they are wanted in their own countries), the under-representation of minorities and women, and the reduced numbers of students able and willing to take on the scholastic rigors necessary for a science or engineering degree. Though much has been written about improving science education, and numerous projects have been conducted to promote it, few education researchers have questioned the scientists themselves about the experiences, practices, and people that positively influenced them, particularly during their pre-college years. Towards this end, thirty-two scientists were interviewed in order to address four research questions: (1) How did practicing scientists' personal relationships with their science teachers influence their decision to pursue a career in science? (2) What pedagogical methods (e.g. lectures, demonstrations, "hands-on" work, problem solving, small groups) used in their high school science courses, if any, played a significant role in propelling certain students towards a career as a practicing scientist? (3) What high school science-related support structures (e.g. labs, equipment, textbooks, technology), if any, played a significant role in propelling certain students towards a career as a practicing scientist? (4) What high school science-related educational activities (e.g. science fairs, clubs, summer internships), if any, played a significant role in propelling certain students towards a career as a practicing scientist? Some of the scientists reported that they knew they were headed towards a career in science before they even entered high school, while others did not make a decision about a science career until after they had graduated from college. The prevailing conviction, however, was that the encouragement from others (though not exclusively by teachers), the excellence of teaching (regardless of pedagogical style), and the richness of science related experiences were the most influential factors in either maintaining or initiating a persistence in science towards a career.

Turkish Adaptation of Questionnaire on Attitudes towards Engineers and Scientists

ERIC Educational Resources Information Center

Ergün, Aysegül; Balçin, Muhammed Dogukan

2017-01-01

The aim of this research was to present the Turkish adaptation of the survey for Middle-School Students' Attitudes toward Engineers and Scientists prepared by Lyons, Fralick and Kearn (2009) 32 items in a 5-point Likert type scale. The questionnaire was administered to 707 students receiving education in the fifth, sixth, seventh and eighth grades…

One Model for Scientist Involvement in K-12 Education: Teachers Experiencing Antarctica and the Arctic Program

NASA Astrophysics Data System (ADS)

Meese, D.; Shipp, S. S.; Porter, M.; Bruccoli, A.

2002-12-01

Scientists involved in the NSF-funded Teachers Experiencing Antarctica and the Arctic (TEA) Program integrate a K-12 science teacher into their polar field project. Objectives of the program include: having the science teacher immersed in the experience of research; 2) through the teacher, leveraging the research experience to better inform teaching practices; and 3) sharing the experience with the broader educational and general community. The scientist - or qualified team member - stays involved with the teacher throughout the program as a mentor. Preparation of the teacher involves a week-long orientation presented by the TEA Program, and a two week pre-expedition visit at the scientist's institution. Orientation acquaints teachers with program expectations, logistical information, and an overview of polar science. While at the scientist's institution, the teacher meets the team, prepares for the field, and strengthens content knowledge. In the field, the teacher is a team member and educational liaison, responding to questions from students and colleagues by e-mail, and posting electronic journals describing the research experience. Upon return, the teachers work closely with colleagues to bring the experience of research into classrooms through creation of activities, design of longer-term student investigations, and presentations at scientific, educational, and community meetings. Interaction with the scientific team continues with a visit by the scientist to the teacher's classrooms, collaboration on presentations at scientific meetings, and consultation on classroom activities. In some cases, the teacher may participate in future expeditions. The involvement by scientists in mentor relationships, such as those of the TEA Program, is critical to improving science education. Many teachers of science have not had the opportunity to participate in field research, which offers valuable first-hand experience about the nature of science, as well as about specific content. The value to the scientist lies in deepening the understanding of current science education, increasing exposure to new ways to communicate information, and developing a path to having the research shared with the classroom and community via the TEA teacher's outreach. This long-term interaction between a scientist and a teacher can result in meaningful impact through increasing depth of understanding - not just about science content, but about the process of science. Equipped with this understanding based on experience, the teacher can multiply the impact with colleagues and students.

A Case Study in the Use of Primary Literature in the Context of Authentic Learning Pedagogy in the Undergraduate Neuroscience Classroom.

PubMed

O'Keeffe, Gerard W; McCarthy, Marian M

2017-01-01

Providing opportunities for undergraduate science students to develop causal reasoning skills and the ability to think like research scientists is a crucial part of their preparation for professional practice as a scientist and/or a clinician. This has led many to question whether the traditional academic in-class lecture still has a functional role in today's undergraduate science education. Here, we performed a case study to attempt to maximize the use of in-class time to create a more authentic learning opportunity for undergraduate neuroscience students in our institution, the majority of whom go on to be research active scientists. We hypothesised that using seminal research papers as a teaching tool in a flipped classroom setting would model for neuroscience students what it means to think like a research scientist, would provide an opportunity for them to develop their causal reasoning skills and allow them to become more comfortable with the nature of professional practice (i.e., research) in the context of the discipline. We describe the design and implementation of this teaching approach to undergraduate final year neuroscience students, and evaluate their perception of it. We provide evidence that this approach models for the students what it means to reason like a research scientist, and discuss the implications of these findings for future practice. We propose that these findings will help add to the educational experience of all Neuroscience students whether they are on pre-med or on a research track.

Arctic Climate Connections Curriculum: A Model for Bringing Authentic Data into the Classroom

ERIC Educational Resources Information Center

Gold, Anne U.; Kirk, Karin; Morrison, Deb; Lynds, Susan; Sullivan, Susan Buhr; Grachev, Andrey; Persson, Ola

2015-01-01

Science education can build a bridge between research carried out by scientists and relevant learning opportunities for students. The Broader Impact requirements for scientists by funding agencies facilitate this connection. We propose and test a model curriculum development process in which scientists, curriculum developers, and classroom…

Evaluation of Changes in Ghanaian Students' Attitudes Towards Science Following Neuroscience Outreach Activities: A Means to Identify Effective Ways to Inspire Interest in Science Careers.

PubMed

Yawson, Nat Ato; Amankwaa, Aaron Opoku; Tali, Bernice; Shang, Velma Owusua; Batu, Emmanuella Nsenbah; Asiemoah, Kwame; Fuseini, Ahmed Denkeri; Tene, Louis Nana; Angaandi, Leticia; Blewusi, Isaac; Borbi, Makafui; Aduku, Linda Nana Esi; Badu, Pheonah; Abbey, Henrietta; Karikari, Thomas K

2016-01-01

The scientific capacity in many African countries is low. Ghana, for example, is estimated to have approximately twenty-three researchers per a million inhabitants. In order to improve interest in science among future professionals, appropriate techniques should be developed and employed to identify barriers and correlates of science education among pre-university students. Young students' attitudes towards science may affect their future career choices. However, these attitudes may change with new experiences. It is, therefore, important to evaluate potential changes in students' attitudes towards science after their exposure to experiences such as science outreach activities. Through this, more effective means of inspiring and mentoring young students to choose science subjects can be developed. This approach would be particularly beneficial in countries such as Ghana, where: (i) documented impacts of outreach activities are lacking; and (ii) effective means to develop scientist-school educational partnerships are needed. We have established an outreach scheme, aimed at helping to improve interaction between scientists and pre-university students (and their teachers). Outreach activities are designed and implemented by undergraduate students and graduate teaching assistants, with support from faculty members and technical staff. Through this, we aim to build a team of trainee scientists and graduates who will become ambassadors of science in their future professional endeavors. Here, we describe an approach for assessing changes in junior high school students' attitudes towards science following classroom neuroscience outreach activities. We show that while students tended to agree more with questions concerning their perceptions about science learning after the delivery of outreach activities, significant improvements were obtained for only two questions, namely "I enjoy science lessons" and "I want to be a scientist in the future." Furthermore, there was a generally strong trend towards a change in attitude for questions that sought information about students' perceptions about scientists (both positive and negative perceptions). In addition, outreach providers reported that their involvement in this public engagement scheme helped them acquire several transferable skills that will be beneficial in their studies and career development. These include vital skills in project and time management, teamwork and public speaking. Altogether, our findings provide novel indications that the development of scientist-school outreach partnerships in Ghana has valuable implications for science education and capacity development.

Students' Representations of Scientific Practice during a Science Internship: Reflections from an Activity-Theoretic Perspective

ERIC Educational Resources Information Center

Hsu, Pei-Ling; van Eijck, Michiel; Roth, Wolff-Michael

2010-01-01

Working at scientists' elbows is one suggestion that educators make to improve science education, because such "authentic experiences" provide students with various types of science knowledge. However, there is an ongoing debate in the literature about the assumption that authentic science activities can enhance students' understandings…

From Research Scientist to Public Outreach: A Personal Journey

NASA Astrophysics Data System (ADS)

Stewart, R.

2004-12-01

Over the past six years I have made the transition from research oceanographer to an educator and public outreach specialist. The transition has been rewarding but difficult. On the way I had to learn the vocabulary and concepts of education (e.g. authentic assessment), effective web-page styles, and the difference between science and education--they are very different. I also met many enthusiastic and caring teachers who greatly eased my transition to educator. Some lessons learned. First, partner with experts. Successful outreach is a team effort. I was luck to have the opportunity to work closely with a great professor of education, Robert James, a wonderful middle-school teacher and Presidential Awardee, Margaret Hammer, and talented students, Jon Reisch and Don Johnson, from our School of ArchitectureAƒAøAøâ_sA¬Aøâ_zAøs Visualization Laboratory, who combined art and technology. Second, if you are a scientist, realize that scientists are too critical. We look for the one right answer, and for the flaws in data and theory. Educators look for the many ways to present ideas, all equally valid, and they value the worth of all students. AƒAøAøâ_sA¬A.â_oSo radical are the differences between the worlds of science and human affairs that their demands are sometimes in conflict.AƒAøAøâ_sA¬A_A¿A 1/2 -Philander: Our Affair With El Nino, p.5. Second, the web is a very efficient way of reaching many people. Thus, web skills are essential. Third, I am learning to be humble. There is much I need to learn. The skills necessary to be a successful research scientist are not sufficient for being a successful educator. Fourth, assess, assess, and assess. DonAƒAøAøâ_sA¬Aøâ_zAøt assume that what you create serves its purpose. Get feedback from educators, students, and scientists of all levels of experience.

Hispanic Student-Scientists

ERIC Educational Resources Information Center

La Luz, 1977

1977-01-01

The Minority Biomedical Support Program provides grant money to educational institutions so they can better encourage and train their students to pursue successful careers in biomedical research. (NQ)

Thinking Like a Scientist About Real-World Problems: The Cornell Institute for Research on Children Science Education Program

ERIC Educational Resources Information Center

Williams, Wendy, M.; Papierno, Paul, B.; Makel, Matthew, C.; Ceci, Stephen, J.

2004-01-01

We describe a new educational program developed by the Cornell Institute for Research on Children (CIRC), a research and outreach center funded by the National Science Foundation. Thinking Life A Scientist targets students from groups historically underrepresented in science (i.e., girls, people of color, and people from disadvantaged…

Creating Successful Scientist-Teacher-Student Collaborations: Examples From the GLOBE Program

NASA Astrophysics Data System (ADS)

Geary, E.; Wright, E.; Yule, S.; Randolph, G.; Larsen, J.; Smith, D.

2007-12-01

Actively engaging students in research on the environment at local, regional, and globe scales is a primary objective of the GLOBE (Global Learning and Observations to Benefit the Environment) Program. During the past 18 months, GLOBE, an international education and science program in 109 countries and tens of thousands of schools worldwide, has been working with four NSF-funded Earth System Science Projects to involve K-12 students, teachers, and scientists in collaborative research investigations of Seasons and Biomes, the Carbon Cycle, Local and Extreme Environments, and Watersheds. This talk will discuss progress to date in each of these investigation areas and highlight successes and challenges in creating effective partnerships between diverse scientific and educational stakeholders. More specifically we will discuss lessons learned in the following areas: (a) mutual goal and responsibility setting, (b) resource allocation, (c) development of adaptable learning activities, tools, and services, (d) creation of scientist and school networks, and (e) development of evaluation metrics, all in support of student research.

Okeanos Explorer 2014 Gulf of Mexico Expedition: engaging and connecting with diverse and geographically dispersed audiences

NASA Astrophysics Data System (ADS)

Russell, C. W.; Elliott, K.; Lobecker, E.; McKenna, L.; Haynes, S.; Crum, E.; Gorell, F.

2014-12-01

From February to May 2014, NOAA Ship Okeanos Explorer conducted a telepresence-enabled ocean exploration expedition addressing NOAA and National deepwater priorities in the U.S. Gulf of Mexico. The community-driven expedition connected diverse and geographically dispersed audiences including scientists from industry, academia, and government, and educators, students, and the general public. Expedition planning included input from the ocean science and management community, and was executed with more than 70 scientists and students from 14 U.S. states participating from shore in real time. Training the next generation permeated operations: a mapping internship program trained undergraduate and graduate students; an ROV mentorship program trained young engineers to design, build and operate the system; and undergraduate through doctoral students around the country collaborated with expedition scientists via telepresence. Online coverage of the expedition included background materials, daily updates, and mission logs that received more than 100,000 visits by the public. Live video feeds of operations received more than 700,000 views online. Additionally, professional development workshops hosted in multiple locations throughout the spring introduced educators to the Okeanos Explorer Educational Materials Collection and the live expedition, and taught them how to use the website and education resources in their classrooms. Social media furthered the reach of the expedition to new audiences, garnered thousands of new followers and provided another medium for real-time interactions with the general public. Outreach continued through live interactions with museums and aquariums, Exploration Command Center tours, outreach conducted by partners, and media coverage in more than 190 outlets in the U.S. and Europe. Ship tours were conducted when the ship came in to port to engage local scientists, ocean managers, and educators. After the expedition, data and products were archived and quickly shared with ocean managers and scientists working in the region, providing a baseline of publicly available data and stimulating follow-on exploration, research and management activities within a few months of expedition completion.

Promoting an Inclusive Image of Scientists among Students: Towards Research Evidence-Based Practice

ERIC Educational Resources Information Center

Cakmakci, Gultekin; Tosun, Ozge; Turgut, Sebnem; Orenler, Sefika; Sengul, Kubra; Top, Gokce

2011-01-01

This study aims at investigating the effects of a teaching intervention, the design of which is informed by evidence from educational theories and research data, on students' images of scientists. A quasi-experimental design with a non-equivalent pre-test-post-test control group (CG) was used to compare the outcomes of the intervention. The…

Engaging Scientists in NASA Education and Public Outreach: Tools for Scientist Engagement

NASA Astrophysics Data System (ADS)

Buxner, Sanlyn; Meinke, B. K.; Hsu, B.; Shupla, C.; Grier, J. A.; E/PO Community, SMD

2014-01-01

The NASA Science Education and Public Outreach Forums support the NASA Science Mission Directorate (SMD) and its education and public outreach (E/PO) community through a coordinated effort to enhance the coherence and efficiency of SMD-funded E/PO programs. The Forums foster collaboration between scientists with content expertise and educators with pedagogy expertise. We present tools and resources to support astronomers’ engagement in E/PO efforts. Among the tools designed specifically for scientists are a series of one-page E/PO-engagement Tips and Tricks guides, a sampler of electromagnetic-spectrum-related activities, and NASA SMD Scientist Speaker’s Bureau (http://www.lpi.usra.edu/education/speaker). Scientists can also locate resources for interacting with diverse audiences through a number of online clearinghouses, including: NASA Wavelength, a digital collection of peer-reviewed Earth and space science resources for educators of all levels (http://nasawavelength.org), and EarthSpace (http://www.lpi.usra.edu/earthspace), a community website where faculty can find and share teaching resources for the undergraduate Earth and space sciences classroom. Learn more about the opportunities to become involved in E/PO and to share your science with students, educators, and the general public at http://smdepo.org.

Finding Meaningful Roles for Scientists in science Education Reform

NASA Astrophysics Data System (ADS)

Evans, Brenda

Successful efforts to achieve reform in science education require the active and purposeful engagement of professional scientists. Working as partners with teachers, school administrators, science educators, parents, and other stakeholders, scientists can make important contributions to the improvement of science teaching and learning in pre-college classrooms. The world of a practicing university, corporate, or government scientist may seem far removed from that of students in an elementary classroom. However, the science knowledge and understanding of all future scientists and scientifically literate citizens begin with their introduction to scientific concepts and phenomena in childhood and the early grades. Science education is the responsibility of the entire scientific community and is not solely the responsibility of teachers and other professional educators. Scientists can serve many roles in science education reform including the following: (1) Science Content Resource, (2) Career Role Model, (3) Interpreter of Science (4) Validator for the Importance of Learning Science and Mathematics, (5) Champion of Real World Connections and Value of Science, (6) Experience and Access to Funding Sources, (7) Link for Community and Business Support, (8) Political Supporter. Special programs have been developed to assist scientists and engineers to be effective partners and advocates of science education reform. We will discuss the rationale, organization, and results of some of these partnership development programs.

Measured and perceived effects of computerized scientist mentors on student learning and motivation in science

NASA Astrophysics Data System (ADS)

Bowman, Catherine Dodds Dunham

Unease about declining U.S. science literacy and inquiry skills drives much innovation in science education, including the quest for authentic science experiences for students. One response is student-scientist partnerships (SSP), involving small numbers of students in scientific investigations with scientist mentors. Alternatively, science inquiry programs provide large numbers of students with opportunities to pursue their own investigations but without extensive access to experts, potentially limiting the possible cognitive and affective gains. This mixed methods study investigates whether it is possible to replicate some of SSPs' benefits on a larger scale through use of a computerized agent designed as a "virtual" scientist mentor. Middle school students (N=532) were randomly assigned to two versions of an agent (or to a control group) providing either content-only or content and interpersonal mentoring while they participated in a three-week curriculum. Results indicate that, on average, students gained in content knowledge but there was no statistically significant difference between the three conditions. In terms of motivation, students exhibited no change, on average, with no statistically significant difference between the three conditions. These data indicate that the treatment conditions neither facilitate nor inhibit student learning and motivation. Interviews with a subsample (n=70), however, suggest that students believe the agents facilitated their learning, eased the workload, provided a trusted source of information, and were enjoyable to use. Teachers reported that the agents provided alternative views of scientists and science, generated class discussion, and met the needs of high and low-achieving students. This difference between measured and perceived benefits may result from measures that were not sufficiently sensitive to capture differences. Alternatively, a more sophisticated agent might better replicate mentoring functions known to produce cognitive and affective gains. Even without established learning or motivational gains, practitioners may want to employ agents for their ability to provide reliable information, expanded perspectives on science and scientists, and a non-intimidating setting for students to ask questions. For computerized agent researchers, this study provides a first step in exploring the affordances and challenges of sustained use of agents in real school settings with the goal of improving science education.

Redefining Scientist-Educator Partnerships: Science in Service at Stanford

NASA Astrophysics Data System (ADS)

Beck, K.

2005-05-01

The Stanford Solar Observatories Group and Haas Center for Public Service have created an innovative model for scientist-educator partnerships in which science students are trained and mentored by public service education professionals to create outreach events for local communities. The program, Science in Service, is part of the EPO plan for the Solar Group's participation in NASA's Solar Dynamics Observatory mission. Based on the principles of service learning, the Science in Service Program mentors college science students in best practices for communicating science and engages these students in public service projects that center on teaching solar science. The program goals are to - Enhance and expand the learning experiences that pre-college students, from underserved and underrepresented groups in particular, have in science and technology. - Promote leadership in community service in the area of science and engineering among the next generation of scientists and engineers, today's undergraduate students. - Encourage science and engineering faculty to think creatively about their outreach requirements and to create a community of faculty committed to quality outreach programs. This talk will describe the unique advantages and challenges of a research-public service partnership, explain the structure of Stanford's Science in Service Program, and present the experiences of the undergraduates and the outreach communities that have been involved in the program.

Building Learning Communities for Research Collaboration and Cross-Cultural Enrichment in Science Education

NASA Astrophysics Data System (ADS)

Sparrow, E. B.

2003-12-01

The GLOBE program has provided opportunities for environmental science research and education collaborations among scientists, teachers and K-12 students, and for cross-cultural enrichment nationally and abroad. In Alaska, GLOBE has also provided funding leverage in some cases, and a base for several other science education programs that share a common goal of increasing student interest, understanding, process skills and achievement in science, through involvement in ongoing research investigations. These programs that use GLOBE methodologies (standardized scientific measurements and learning activities developed by scientists and educators) are: Global Change Education Using Western Science and Native Knowledge also known as "Observing Locally, Connecting Globally" (OLCG); Alaska Earth System Science Education Alliance: Improving Understanding of Climate Variability and Its Relevance to Rural Alaska; Schoolyard Long Term Ecological Research; Alaska Rural Research Partnership; Alaska Partnership for Teacher Enhancement; Alaska Lake Ice and Snow Observatory Network; Alaska Boreal Forest Council Education Outreach; Calypso Farm and Ecology Center; Environmental Education Outreach; and also GLOBE Arctic POPs (persistent organic pollutants) a program that involves countries in the circumpolar North. The University of Alaska GLOBE Partnership has collaborated with the BLM Campbell Creek Science Center Globe Partnership in facilitating GLOBE Training Workshops and providing teacher support. GLOBE's extensive website including data entry, archive, analysis and visualization capabilities; GLOBE Teacher Guide, videos and other materials provided; excellent GLOBE science research and education staff, training support office, GLOBE help desk, alignment of GLOBE curriculum with national science education standards and GLOBE certification of teachers trained on even just one GLOBE investigation, have made it easier to implement GLOBE in the classroom. Using GLOBE, whole classes of students have engaged in and contributed data to science investigations. In Alaska, classes and individual students have conducted their own inquiry studies and have successfully presented their investigations and competed at science fairs and statewide high school science symposium and international conferences. Two students presented their research investigations at the GLOBE Learning Expedition in Croatia and four students presented their study at the GLOBE Arctic POPs Conference in Sweden. These students increased not only their understanding and knowledge of science but also in appreciation of people in other countries and their cultures. Friendships have also bloomed. The learning community in Alaska has expanded to include family and community members including Native elders (using OLCG), teachers, scientists and students from other countries. The following challenges remain: 1) getting funds to be able to provide GLOBE equipment and continuous support to GLOBE teachers and students throughout the year, 2) reaching teachers and students in remote areas, 3) rapid teacher turn-over rate in rural areas, 4) using inquiry-based pedagogies during GLOBE professional development workshops including the opportunity for teacher participants to conduct their own inquiries during the workshop, 5) time, school curriculum and national education requirement constraints, 6) involving school administrators, and more local scientists and community members, and 7) providing culturally relevant and responsive science education programs and life-long learning communities.

One-Two Punch: Utilizing Teacher Research Experiences and Related Classroom Activities to Increase Student Interest in STEM

NASA Astrophysics Data System (ADS)

Wold-Brennon, R.; Cooper, S. K.

2014-12-01

Through collaborations between scientists and educators, the Consortium for Ocean Leadership developed a series of marine geosciences classroom activities and lesson plans -- including the Adopt-a-Microbe project, a collection of hands-on science lessons that use the sub-seafloor microbiology topics to provide engaging pathways for K-12 students to learn about the world around them. The goal of these activities has been to introduce youth to deep ocean exploration, inspire interest in microbial oceanography, and foster higher education goals and career paths in related sciences for our youth. From the beginning, these lessons were developed in close working relationships between scientists and educators, and the lessons geared towards middle school have been recently piloted with the intent to maximize sustained student interest in STEM topics. While teaching these units, educators used surveys, polls, group discussions, and interviews to shed light on correlations between student interest in STEM and their close proximity to exemplary and enthusiastic educators and student leaders who are active in STEM activities such as research projects and expeditions. Educators continue to use Adopt-a-Microbe and related expedition science-based lessons to explore the broader impacts of their professional development in the Geosciences on their students' professed interest in STEM.

Going beyond the textbook: The need to integrate open access primary literature into the Chemistry curriculum

PubMed Central

2011-01-01

Unrestricted, open access to scholarly scientific literature provides an opportunity for chemistry educators to go beyond the textbook, introducing students to the real work of scientists. Despite the best efforts of textbook authors to provide information about recent research results, textbooks are not a substitute for learning to use the primary literature. Chemical educators can use open access articles to develop research-related skills, to foster curiosity, and to cultivate the next generation of scientists. It is becoming increasingly important for chemical educators to teach undergraduates how online journals are changing the nature of chemical research. Some institutions can not afford online subscription costs, and open access journals can be an important resource to provide practical experience. Open access publications eliminate the barriers to the central work of scientists providing chemistry educators (whether at well-endowed or economically limited colleges) with the key resources for enhancing student learning through current, relevant research. PMID:21470429

Getting the Word Out: Teaching Middle-School Children about Cardiovascular Disease

PubMed Central

Toepperwein, Mary Anne; Pruski, Linda A.; Blalock, Cheryl L.; Lemelle, Olivia R.; Lichtenstein, Michael J.

2008-01-01

Cardiovascular disease (CVD) has roots in childhood; since CVD begins early, a clear strong case for early education focused on CVD primary prevention exists. Scientists are not traditionally involved in disseminating health knowledge into public education. Similarly, public school teachers typically do not have access to biomedical research that may increase their students’ health science literacy. One way to bridge the ‘cultural’ gap between researchers and school teachers is to form science education partnerships. In order for such partnerships to be successful, teams of scientists and teachers must ‘translate’ biomedical research into plain language appropriate for students. In this article, we briefly review the need for improving health literacy, especially through school-based programs, and describe work with one model scientist/teacher partnership, the Teacher Enrichment Initiatives. Examples of cardiovascular research ‘translated’ into plain language lessons for middle school students are provided and practical considerations for researchers pursuing a science education partnership are delineated. PMID:19122871

Geoscientist/Educator Partnerships at the University of Colorado: Strategies and Examples

NASA Astrophysics Data System (ADS)

Buhr, S. M.; Hare, J.; Healy, G.

2005-05-01

According to a study about the factors that engage and hinder scientists' involvement in education and outreach (Andrews et.al., 2005), the presence of a dedicated outreach coordinator who can provide a point of contact and lessen the burden on scientists is one of the keys to success. For the past nine years, research scientists at the Cooperative Institute for Research in Environmental Sciences (CIRES) have worked in partnership with just such a coordinating team, the CIRES Education and Outreach group. As funding agency emphasis on education and social impacts has increased, so have the opportunities to develop educational projects intrinsically linked to current geoscience research. One such effort is Ocean Interactions, a project which began as a ship-shore student communication opportunity at the initiation of the researcher. The roles of each contributor to the partnership will be described, along with the framework through which CIRES supports scientist/educator partnerships of this sort. Andrews, Elisabeth, Alexandra Weaver, Daniel Hanley, Jeff Hovermill, Ginger Melton. 2005. "Scientists and Public Outreach: Participation, Motivations and Impediments." Journal of Geoscience Education in press May 2005.

Connecting Scientists, College Students, Middle School Students & Elementary Students through Intergenerational Afterschool STEM Programming

NASA Astrophysics Data System (ADS)

Ali, N. A.; Paglierani, R.; Raftery, C. L.; Romero, V.; Harper, M. R.; Chilcott, C.; Peticolas, L. M.; Hauck, K.; Yan, D.; Ruderman, I.; Frappier, R.

2015-12-01

The Multiverse education group at UC Berkeley's Space Sciences Lab created the NASA-funded "Five Stars Pathway" model in which five "generations" of girls and women engage in science together in an afterschool setting, with each generation representing one stage in the pathway of pursuing a career in science, technology, engineering, or math (STEM). The five stages are: elementary-age students, middle-school-age students, undergraduate-level college students, graduate-level college students and professional scientists. This model was field-tested at two Girls Inc. afterschool locations in the San Francisco Bay Area and distributed to Girls Inc. affiliates and other afterschool program coordinators nationwide. This presentation will explore some of the challenges and success of implementing a multigenerational STEM model as well as distributing the free curriculum for interested scientists and college students to use with afterschool programs.

Students' Engagement Profiles in Mathematics According to Learning Environment Dimensions: Developing an Evidence Base for Best Practice in Mathematics Education

ERIC Educational Resources Information Center

Watt, Helen M. G.; Carmichael, Colin; Callingham, Rosemary

2017-01-01

The Best Practice in Mathematics Education project was funded by the Australian Office of the Chief Scientist, to examine promotion of students' learning, engagement and aspirations in this core learning domain. We draw upon cross-sectional survey data from 551 students in grades three to nine to examine how students' mathematics engagement…

A Case Study in the Use of Primary Literature in the Context of Authentic Learning Pedagogy in the Undergraduate Neuroscience Classroom

PubMed Central

O’Keeffe, Gerard W.; McCarthy, Marian M.

2017-01-01

Providing opportunities for undergraduate science students to develop causal reasoning skills and the ability to think like research scientists is a crucial part of their preparation for professional practice as a scientist and/or a clinician. This has led many to question whether the traditional academic in-class lecture still has a functional role in today’s undergraduate science education. Here, we performed a case study to attempt to maximize the use of in-class time to create a more authentic learning opportunity for undergraduate neuroscience students in our institution, the majority of whom go on to be research active scientists. We hypothesised that using seminal research papers as a teaching tool in a flipped classroom setting would model for neuroscience students what it means to think like a research scientist, would provide an opportunity for them to develop their causal reasoning skills and allow them to become more comfortable with the nature of professional practice (i.e., research) in the context of the discipline. We describe the design and implementation of this teaching approach to undergraduate final year neuroscience students, and evaluate their perception of it. We provide evidence that this approach models for the students what it means to reason like a research scientist, and discuss the implications of these findings for future practice. We propose that these findings will help add to the educational experience of all Neuroscience students whether they are on pre-med or on a research track. PMID:29371836

Educating Chinese Scientists to Write for International Journals: Addressing the Divide between Science and Technology Education and English Language Teaching

ERIC Educational Resources Information Center

Cargill, Margaret; O'Connor, Patrick; Li, Yongyan

2012-01-01

As is the worldwide trend, scientists in China face strong and increasing pressure to publish their research in international peer-reviewed journals written in English. There is an acute need for graduate students to develop the required language skills alongside their scientific expertise, in spite of the distinct division currently existing…

Exploring the Sky: An Exploratory Study on the Effectiveness of Discourse in an Atmospheric Science Outreach Program

NASA Astrophysics Data System (ADS)

Boyd, K.; Balgopal, M.; Birner, T.

2015-12-01

Educational outreach programs led by scientists or scientific organizations can introduce participants to science content, increase their interest in science, and help them understand the nature of science (NOS). Much of atmospheric science (AS) educational outreach to date has concentrated on teacher professional development programs, but there is still a need to study how students react to classroom programs led by scientists. The purpose of this research project is to examine student engagement with AS and NOS content when presented by a university atmospheric scientist or an Earth system science teacher. The guiding research question was: how do students interact with science experts in their classrooms compared to their teachers when learning about Earth science and NOS? The outreach program was developed by an AS faculty member and was implemented in a local 10th grade Earth Science class. The presenter used historical stories of discoveries to introduce concepts about the middle atmosphere and climate circulations, reinforcing the NOS in his interactive presentations. On a separate day the teacher implemented a lesson on plate tectonics grounded in NOS. A case study analysis is being conducted using videotaped presentations on Earth science and NOS by the teacher and the scientist, pre- and post- questionnaires, and teacher and scientist interviews in order to determine patterns in student-presenter discourse, the levels of presenters' inquiry-based questioning, and the depth of student responses around Earth science content and NOS. Preliminary results from video analysis indicate that the scientist used higher inquiry-based questioning strategies compared to the teacher; however the teacher was able to go into more depth on a topic with the lesson. Scientists must consider whether the trade-offs warrant focusing their outreach efforts on content professional development for teachers or content outreach for K-12 students.

SEAS Classroom to Sea Labs: New Directions for Ridge 2000 Communitywide Education Outreach

NASA Astrophysics Data System (ADS)

Goehring, L.

2005-12-01

Lessons learned from the two year SEAS pilot program emphasize that student participation in deep-sea research is an important motivator in student learning. Further, SEAS students experience a paradigm shift in understanding evidence-based reasoning and the process of scientific discovery. At the same time, we have learned that fostering authentic student investigations within the confines of the academic year is challenging and only fits classrooms with some academic flexibility. As a result, this year, SEAS will focus on the new Classroom to Sea Lab as a means to help foster student inquiry in the secondary school science classroom. The Classroom to Sea Lab invites student participation in deep-sea research but does so without requiring students to identify and propose suitable sea-going experiments. Classroom to Sea labs are designed to feature current deep-sea research, and emphasize critical skills in laboratory techniques, data collection and analysis, and scientific reporting. Labs are conducted in the classroom (by students) and at sea (by scientists for the students), resulting in parallel datasets for comparison. Labs also feature the work of practicing scientists. An annual Classroom to Sea Report Fair invites students to summarize their findings and submit written analyses for scientist feedback and prizes, emphasizing the importance of communications skills in science. This year, the SEAS program will feature the Shallow-water vs. Deep-sea Vent Mussel Classroom to Sea lab. In this lab, students explore differences in mussel anatomy and feeding strategies, and understand how chemosynthetic symbionts function in this animal. The lab instructs students to dissect shallow-water mussels and measure the proportion of gill tissue to total body tissue. Students are also instructed to download a dataset of vent mussel measurements and compare average proportions. Finally, students are invited to submit their analyses of the lab to the on-line Report Fair sponsored by the Ridge 2000 research community. A primary goal of SEAS is to excite and engage student learners by involving them in actual research in the extreme environments of the deep-sea. The program depends on the contributions of multiple scientists within the Ridge 2000 community. Scientists field student questions during the Ask-a-Scientist email forum, serve as Report Reviewers, are featured in ``Scientist Spotlights,'' host educators during cruises to conduct at-sea portions of a lab, and help develop new labs. It is community involvement that makes the SEAS program possible and so exciting and motivating for students.

Students and Teachers Exploring Live the Limits of Life on Earth with a Nasa/seti Expedition to the Highest Lakes on Earth

NASA Astrophysics Data System (ADS)

Cabrol, N. A.; Grigsby, B. H.

2004-12-01

"Life at the Extreme" is an education and public outreach (E/PO) project that engaged teachers and 4-12th grade students (an in part, Prek-3rd grade students) in an internet-based, virtual expedition with scientists as they conducted experiments in a unique planetary analog environment in the Bolivian High-Andes at nearly 6,000 m (~20,000ft). Through high altitude diving and sampling, they explored the Licancabur volcano summit lake, which is one of the closest analogs to ancient lakes on Mars. Their goal was to characterize the environment and to study the defense strategies of life against extreme physical conditions in order to understand the biological potential of Mars and prepare future planetary missions. This "virtual field" was in the form of an interactive web site, live interactive discussions, a live video webcast with the San Francisco Exploratorium, and videotapes. Through this medium, about 2,700 students, 90 schools and teachers were able to directly participate and extend their knowledge of scientific processes as they explored an extreme and unique terrestrial environment. In the weeks leading up to the expedition, and during in-the-field activities, students were able to communicate with scientists as they prepared for and conducted scientific investigations. The general public could follow the expedition as well on the web. Overall, the website received ~70,000 hits from all over the world during the time of the expedition. Allowing this access to scientists as they performed their investigations proved invaluable as students understood the implications of scientific work. The broader impact of this experience provided ground work for other educational institutions to conduct similar activities with leading scientists and bridge the gap that often exists between scientists and education. The project was conducted in partnership with the NASA's Ames Research Center's expedition to the Licancabur volcano, located on the border between Chile and Bolivia and is the location of one of the least explored lakes in the world. K-12 educators played a key roll in the development and implementation of curriculum for this project. In 2002, a teacher accompanied the scientific team to the summit to document their research for the benefit of all k-12 educators both as the exploration occurs and as an ongoing educational enquiry. The virtual field experience was funded through an IDEAS (The Initiative to Develop Education through Astronomy and Space Science) grant. The 2002-03, and 2003-04 virtual field experience can be found at: http://www.extremeenvironment.com.

Scientists and K-12: Experience from The Science House

NASA Astrophysics Data System (ADS)

Haase, David G.

2003-03-01

In working with K-12 science and mathematics education, scientists may take on many different roles - from presenter to full-time partner. These roles are illustrated in the activities of The Science House, a K-12 education program of North Carolina State University, (www.science-house.org) which partners with teachers and students across the state to promote inquiry-based learning in mathematics and science. While it is important to involve scientists in K-12, most universities do not have effective means to make the connections. In our efforts to do so, which began with a few teacher workshops and now encompasses six offices across NC, we have sought to join the interests of the university (research, teaching, student recruiting) to the needs of K-12. Our programs now include teacher training workshops, student science camps and curriculum projects in several states. We are reminded that K-12 science education is interdisciplinary; local and political; and a process, not a problem to be solved and forgotten. Partially supported by NSF (CHE-9876674 and DBI-0115462), the Howard Hughes Medical Institute and the Burroughs Wellcome Fund.

NASA/State Education Cooperation

NASA Technical Reports Server (NTRS)

1990-01-01

NASA is cooperating with state departments of education in a number of special education programs. An example is Maryland Summer Centers for Gifted and Talented Students sponsored by the Maryland State Department of Education. Some 2,600 students participated in the 1990 program. One of the 12 centers is the Center for Space Science and Technology at Goddard Space Flight Center, which provides instruction to students of the 9-12 grade level. This center is operated by a three organization partnership that includes the Maryland State Department of Education, the University of Maryland and Goddard Space Flight Center, which hosts the instructional program and provides volunteer scientists and engineers as instructors. Typical two-week space intern program includes panel discussions, lectures, tours, field trips and hands-on activity focusing on various space science topics. Senior high students benefit from a one-to-one mentor relationship with a volunteer scientist or engineer. Another example was the Paducah (Kentucky) NASA Community Involvement Project, a joint educational effort of Langley and Lewis Research Centers, Marshall Space Flight Center, the Kentucky Department of Education, the City of Paducah and Paducah Independent Schools. It was a 16 day exposition/symposium featuring seminars on space subjects.

Teaching Scientists to Fish, as Inspired by Jack Dymond

NASA Astrophysics Data System (ADS)

Franks, S. E.

2004-12-01

It is almost inconceivable that as Jack Dymond's graduate student for eight years, I never mastered the skill of fly-fishing, a pursuit so near and dear to his heart. In fact, Jack did inspire me, not to tie flies and cast, but eventually to teach fellow scientists to fish. The work I'll present - connecting scientists and educators to achieve societal benefit - is profoundly influenced by Jack's dedication to applying scientific understanding and critical thinking to societal issues. With colleagues in the Centers for Ocean Sciences Education Excellence (COSEE), http://www.cosee.net/, I enable scientists to efficiently make meaningful contributions to educational outreach. A key goal of the multi-Center, national COSEE Network is helping scientists build the skills and acquire the resources needed to share their science with diverse audiences. At Scripps, we are piloting an innovative approach to helping scientists meet funding agencies' broader impact requirements. Key elements of the approach include: 1) services to identify educational outreach options that best fit scientists' research and preferences; 2) assistance establishing partnerships with educational outreach providers who have the skills and resources to develop and implement effective programs and exhibits; and 3) nuts and bolts (line and fly) assistance writing proposal text, drafting budgets, and coordinating with institutional business offices to ensure that the proposed educational outreach effort is compelling and sufficiently funded. Where does the fishing lesson come in? We facilitators of scientist-educator partnerships empower scientists to launch enduring collaborations. Once comfortable working with top-notch educational organizations, scientists can tap these resources, project after project, often with little or no additional involvement on our part. Our initial investment in brokering the relationships is richly rewarded. By helping scientists get started, it's as if we are teaching them to fish, rather than merely giving them fish.

Informal Physics Education: Outreach from a National Laboratory

NASA Astrophysics Data System (ADS)

Sanchez, Jose; Dixon, Patricia; Hughes, Roxanne

2012-02-01

This presentation highlights strategies for K-20 teaching and learning about materials research in informal settings. The National High Magnetic Field Laboratory's Center for Integrating Research & Learning is in a unique position to conduct programs that reach K-20 students and teachers. As part of a national laboratory the Center provides the infrastructure around which informal education programs are implemented, including the nationally-recognized programming as well as facilitating scientists' educational outreach in the community. Research Experiences for Undergraduates, focuses on encouraging women and other underrepresented groups to pursue STEM careers reaching approximately 200 students many of whom have pursued careers in research as well as academia. The Research Experiences for Teachers program has provided internships for over 150 teachers; the Center also reaches over 10,000 students each year through school and community outreach. Success of informal education programs relies heavily on establishing strong mentoring relationships between scientists and K-20 students and teachers. The Center's success at maintaining diverse programming that transforms how materials education is presented beyond the traditional classroom is the focus for this presentation.

Lunar Reconnaissance Orbiter Lunar Workshops for Educators

NASA Astrophysics Data System (ADS)

Jones, A. P.; Hsu, B. C.; Hessen, K.; Bleacher, L.

2012-12-01

The Lunar Workshops for Educators (LWEs) are a series of weeklong professional development workshops, accompanied by quarterly follow-up sessions, designed to educate and inspire grade 6-12 science teachers, sponsored by the Lunar Reconnaissance Orbiter (LRO). Participants learn about lunar science and exploration, gain tools to help address common student misconceptions about the Moon, find out about the latest research results from LRO scientists, work with data from LRO and other lunar missions, and learn how to bring these data to their students using hands-on activities aligned with grade 6-12 National Science Education Standards and Benchmarks and through authentic research experiences. LWEs are held around the country, primarily in locations underserved with respect to NASA workshops. Where possible, workshops also include tours of science facilities or field trips intended to help participants better understand mission operations or geologic processes relevant to the Moon. Scientist and engineer involvement is a central tenant of the LWEs. LRO scientists and engineers, as well as scientists working on other lunar missions, present their research or activities to the workshop participants and answer questions about lunar science and exploration. This interaction with the scientists and engineers is consistently ranked by the LWE participants as one of the most interesting and inspiring components of the workshops. Evaluation results from the 2010 and 2011 workshops, as well as preliminary analysis of survey responses from 2012 participants, demonstrated an improved understanding of lunar science concepts among LWE participants in post-workshop assessments (as compared to identical pre-assessments) and a greater understanding of how to access and effectively share LRO data with students. Teachers reported increased confidence in helping students conduct research using lunar data, and learned about programs that would allow their students to make authentic contributions to lunar science. Participant feedback on workshop surveys was enthusiastically positive. 2012 was the third and final year for the LWEs in the current funding cycle. They will continue in a modified version at NASA Goddard Space Flight Center in Greenbelt, MD, where the LRO Project Office and Education and Public Outreach Team are based. We will present evaluation results from our external evaluator, and share lessons learned from this workshop series. The LWEs can serve as a model for others interested in incorporating scientist and engineer involvement, data from planetary missions, and data-based activities into a thematic professional development experience for science educators. For more information about the LWEs, please visit http://lunar.gsfc.nasa.gov/lwe/index.html.

Preparing the nurse scientist for academia and industry.

PubMed

Lewallen, Lynne P; Kohlenberg, Eileen

2011-01-01

The number of doctoral programs in nursing has been increasing. However, these programs tend to focus on preparing nurse scientists to conduct research, and many spend little time preparing doctoral students for the educator, clinical researcher, or administrator role. Leaders of doctoral programs have identified the need to prepare doctoral students in the functional roles they will assume upon graduation, in addition to the researcher role. This article describes a two-course (six-credit) sequence of courses within a research-focused PhD in Nursing program that provides didactic and experiential knowledge about the role of the nurse scientist in academia and industry settings. Students are highly satisfied with the courses, and report that the experiences have provided them with important knowledge and skills as they assume the scientist role.

Telling Your Story: Ocean Scientists in the K-12 Classroom

NASA Astrophysics Data System (ADS)

McWilliams, H.

2006-12-01

Most scientists and engineers are accustomed to presenting their research to colleagues or lecturing college or graduate students. But if asked to speak in front of a classroom full of elementary school or junior high school students, many feel less comfortable. TERC, as part of its work with The Center for Ocean Sciences Education Excellence-New England (COSEE-NE) has designed a workshop to help ocean scientists and engineers develop skills for working with K-12 teachers and students. We call this program: Telling Your Story (TYS). TYS has been offered 4 times over 18 months for a total audience of approximately 50 ocean scientists. We will discuss the rationale for the program, the program outline, outcomes, and what we have learned. ne.net/edu_project_3/index.php

Education and Public Outreach for the PICASSO-CENA Satellite-Based Research Mission: K-12 Students Use Sun Photometers to Assist Scientists in Validating Atmospheric Data

NASA Astrophysics Data System (ADS)

Robinson, D. Q.

2001-05-01

Hampton University, a historically black university, is leading the Education and Public Outreach (EPO) portion of the PICASSO-CENA satellite-based research mission. Currently scheduled for launch in 2004, PICASSO-CENA will use LIDAR (LIght Detection and Ranging), to study earth's atmosphere. The PICASSO-CENA Outreach program works with scientists, teachers, and students to better understand the effects of clouds and aerosols on earth's atmosphere. This program actively involves students nationwide in NASA research by having them obtain sun photometer measurements from their schools and homes for comparison with data collected by the PICASSO-CENA mission. Students collect data from their classroom ground observations and report the data via the Internet. Scientists will use the data from the PICASSO-CENA research and the student ground-truthing observations to improve predications about climatic change. The two-band passive remote sensing sun photometer is designed for student use as a stand alone instrument to study atmospheric turbidity or in conjunction with satellite data to provide ground-truthing. The instrument will collect measurements of column optical depth from the ground level. These measurements will not only give the students an appreciation for atmospheric turbidity, but will also provide quantitative correlative information to the PICASSO-CENA mission on ground-level optical depth. Student data obtained in this manner will be sufficiently accurate for scientists to use as ground truthing. Thus, students will have the opportunity to be involved with a NASA satellite-based research mission.

Teaching Graduate Students How To Do Informal Science Education

NASA Astrophysics Data System (ADS)

Ackerman, S. A.; Crone, W.; Dunwoody, S. L.; Zenner, G.

2011-12-01

One of the most important skills a student needs to develop during their graduate days is the skill of communicating their scientific work with a wide array of audiences. That facility will serve them across audiences, from scientific peers to students to neighbors and the general public. Increasingly, graduate students express a need for training in skills needed to manage diverse communicative environments. In response to that need we have created a course for graduate students in STEM-related fields which provides a structured framework and experiential learning about informal science education. This course seeks to familiarize students with concepts and processes important to communicating science successfully to a variety of audiences. A semester-long course, "Informal Science Education for Scientists: A Practicum," has been co-taught by a scientist/engineer and a social scientist/humanist over several years through the Delta Program in Research, Teaching, & Learning at the University of Wisconsin-Madison. The course is project based and understanding audience is stressed throughout the class. Through development and exhibition of the group project, students experience front end, formative and summative evaluation methods. The disciplines of the participating students is broad, but includes students in the geosciences each year. After a brief description of the course and its evolution, we will present assessment and evaluation results from seven different iterations of the course showing significant gains in how informed students felt about evaluation as a tool to determine the effectiveness of their science outreach activities. Significant gains were found in the graduate students' perceptions that they were better qualified to explain a research topic to a lay audience, and in the students' confidence in using and understanding evaluation techniques to determine the effectiveness of communication strategies. There were also increases in the students' understanding of audiences and the iterative process required to design an informal education product.

Developing an Education and Public Outreach (EPO) program for the Caltech Tectonics Observatory

NASA Astrophysics Data System (ADS)

Kovalenko, L.; Nadin, E.; Avouac, J.

2008-12-01

The Caltech Tectonics Observatory (TO) is an interdisciplinary center, focused on geological processes occurring at the boundaries of Earth's tectonic plates. The timescales of these processes span from a few tens of seconds (the typical duration of an earthquake) to tens of millions of years (the time it takes to build mountains). Over the past four years, the TO has brought together 15 Caltech faculty from different fields, several visiting scientists from around the globe, and a few tens of graduate students and postdoctoral students, collaborating on scientific projects. A major objective of the TO now is to develop an Education and Public Outreach (EPO) program. Our goals are to (1) stimulate the interest of students and the general public in Earth Sciences, particularly in the study of tectonic processes, (2) inform and educate the general public about TO discoveries and advancements, and (3) make available the data and techniques developed by the TO for use in classrooms of all levels. To this effect, we have been developing our website for accessibility by the general public and writing educational web articles on TO research. A recent well-visited example is "The science behind the recent 2008 earthquake in China." We distribute animations that illustrate the mechanisms of earthquakes and tsunamis, and the various techniques used by TO scientists in their scientific investigations. The TO website also provides access to geodetic data collected by TO instruments and to the source models of recent large earthquakes as analyzed by TO scientists. The TO hosts tours of its facilities for local elementary school students and is working on developing education modules for high school and undergraduate classes. We are now working on a plan to offer short courses over the summer for undergraduate and graduate students in other institutions, in order to train them to analyze a variety of data and use techniques developed by TO scientists.

The Scientist and the Educational Development Team: An Impedance Mismatch?

NASA Astrophysics Data System (ADS)

Pompea, S. M.

2001-05-01

This talk describes my experiences and those of several other scientists who have worked on teams to develop new instructional materials and programs. At each stage of the development process we try to communicate our skills and experiences to the rest of the development team. In turn, the experiences of non-scientist educators on the team must be communicated to us. However, in many cases there is an "impedance mismatch" which makes communication difficult. One primary source of this mismatch is the scientist's lack of experience with schools, students, teachers, school administrators, museums, and the public. The result of this mismatch can leave the scientist in one limited, but useful role: proofreader and critic. Unfortunately, this can hardly be described as a partnership. This talk gives some advice, based on 25 years of educational materials and program development work, on how to avoid such a limited role. The talk would be appropriate for those scientists who want to lead, inspire, or significantly contribute to educational initiatives and to share in the frustration and the rewards enjoyed by professional educators and professional educational developers. S. Pompea is an adjunct faculty member of Steward Observatory of the University of Arizona.

The ERESE project: Bridging the gap between Digital Science Libraries and Education through Professional Development of Teachers and Database Development

NASA Astrophysics Data System (ADS)

Staudigel, H.; Helly, M.; Helly, J.; Koppers, A.; Massel-Symons, C.; Miller, S.

2004-12-01

The ERESE (Enduring Resources in Earth Science Education) project involves a close collaboration between teachers, librarians, educators, data archive managers and scientists in Earth sciences and information technology, to create a digital library environment for Earth science education. We report here on an ongoing (NSF-NSDL) project involving teachers' professional development in the pedagogy of plate tectonics in middle and high schools. This work included efforts in scientific database development in terms of contents and search tools, the development of an inquiry based learning approach, a two week professional development workshop attended by 15 teachers from across the nation, a classroom implementation of lesson plans developed by the teachers at the workshop and an evaluation/validation process for the success of their pedagogic approaches. This ERESE project offers a novel path for both science teaching and professional outreach for scientists, and includes four key components: (1) A true, long-term research partnership between educators and scientists, guiding each other with respect to the authenticity of the science taught and the educational soundness of a scientists' elaborations on science concepts. (2) Expansion of existing scientific databases through the use of metadata that tie scientific materials to a particular expert level and teaching goal. (3) The design of interfaces that make data accessible to the educational community. (4) The use of an inquiry based teaching approach that integrates the scientist-educator collaboration and the data base developments. Our pedagogic approach includes the development of a central hypotheses by the student in response to an initial general orientation and presentation of a well chosen central provocative phenomenon by the teacher. Then, the student develops a research plan that is devoted to address this hypothesis through the use of the materials provided by a scientific database allowing a students prove or disprove their hypothesis and to explore the limits of the (current) understanding of a particular science question. Our first experience with this ERESE project involved a steep learning curve, but the initial results are very promising, providing true professional development for educators as well as for the scientists, whereby the former learn about new ways of teaching science and the latter learn to communicate with teachers.

The Ocean 180 Video Challenge: An Innovative Outreach Strategy for Connecting Scientists to Classrooms

NASA Astrophysics Data System (ADS)

Tankersley, R. A.; Windsor, J. G.; Briceno, K. V.

2016-02-01

Recognizing the need for scientists to engage and communicate more effectively with the public, the Florida Center for Ocean Sciences Education Excellence (COSEE Florida) created an opportunity to connect the two through film. The Ocean 180 Video Challenge taps into the competitive spirit of scientists and encourages them to submit short, 3-minute video abstracts summarizing the important findings of recent peer-reviewed papers and highlighting the relevance, meaning, and implications of the research to persons outside their discipline. Although the videos are initially screened and evaluated by a team of science and communication experts, the winners (from a field of ten finalists) are selected by middle school students in classrooms all over the world. Since its inception in 2013, Ocean 180 has grown in popularity, with more than 38,000 middle school students from 1,637 classrooms in 21 countries participating as judges. Results of a Draw-a-Scientist Test administered during the 2015 competition indicate Ocean 180 is an successful intervention that has a positive impact on students' views of science, including their perception and attitudes toward scientists and science careers. Thus, our presentation will discuss how video competitions can serve as effective outreach strategies for encouraging scientists to share new discoveries and their enthusiasm for science with K-12 students. We will also highlight the outcomes and lessons-learned from the 2014 and 2015 competitions, including (1) strategies for recruiting teachers and students to participate as judges, (2) approaches used by educators to align the content of videos with state and national science standards, and (3) ways contest videos can be integrated into science training and professional development programs, including workshops focusing on effective video storytelling techniques.

Doctoral Conceptual Thresholds in Cellular and Molecular Biology

ERIC Educational Resources Information Center

Feldon, David F.; Rates, Christopher; Sun, Chongning

2017-01-01

In the biological sciences, very little is known about the mechanisms by which doctoral students acquire the skills they need to become independent scientists. In the postsecondary biology education literature, identification of specific skills and effective methods for helping students to acquire them are limited to undergraduate education. To…

Teaming Up with Scientists.

ERIC Educational Resources Information Center

Moreno, Nancy P.; Chang, Kimberly A.; Tharp, Barbara Z.; Denk, James P.; Roberts, J. Kyle; Cutler, Paula H.; Rahmati, Sonia

2001-01-01

Introduces the Science Education Leadership Fellows (SELF) program which is an innovative cooperation program between teachers and scientists. Engages teachers in subject areas such as microbiology, molecular biology, immunology, and other professional development activities. Presents an activity in which students observe bacteria cultures and…

College student perceptions of science teachers and the effect on science teaching as a career path

NASA Astrophysics Data System (ADS)

Cost, Michael George

2000-10-01

Past research documented that student perceptions of scientists constituted a stereotypical image that had a negative effect on the students' attitudes towards science and resulted in low numbers of students studying to become scientists and engineers in college. The present study paralleled the research on student perceptions of scientists to investigate to what extent student perceptions of science teachers affect their willingness to consider science teaching as a career. This was accomplished by surveying 91 college students and 25 science teachers at the beginning, middle, and end of the collegiate career path of becoming a science teacher. Each survey contained quantitative data utilizing seven-point semantic differential scales and written open response questions. In-depth interviews with two members of each level were conducted to supplement the survey data. The study found that college students begin college with a positive perception of teaching as a career and highly rank teachers, especially science teachers, as having a positive influence on their career path. The qualities of job enjoyment, job stability, and helping others that are characteristic of teaching were also found to be of high importance. Perceptions of the personal, social, professional, and career qualities of a science teacher were found to differ from a scientist. While both science teachers and scientists were found to be responsible, persistent, and productive, science teachers were perceived as being a distinct career possessing qualities that make them more personable, sociable, and wise than scientists. Some gender differences were detected but there was no evidence of gender bias affecting students choosing a career path to science teaching. Science teachers were perceived to be very supportive of females pursuing scientific career paths. The study also found evidence that some introductory level college students steer away from science teaching because of low salary, the lack of promotion, and the efforts of influential people including science teachers. The study calls for departments of science education to take a more active role in the recruitment of new science teachers and the improvement of undergraduate science education.

What do primary students know about science, scientists and how they do their work?

NASA Astrophysics Data System (ADS)

Bartels, Selina L.

The teaching of scientific literacy is the primary goal of elementary science education. Scientific literacy is composed of the overall understanding of what science is and how scientific knowledge is developed. The purpose of this study was to see if elementary students' understandings of science, scientists and how scientists do their work changes from grade one to grade five of elementary school. Furthermore, the study attempts to determine whether there is a difference in scientific literacy between students taught using a textbook curriculum versus a kit-based curriculum. The study draws on a sample of 338 students from 18 different classrooms situated in six different schools in both urban and suburban areas of a large Midwestern city. Students' understandings of science, scientists and how they do their work was measured through a valid and reliable oral protocol entitled Young Children's Views of Science (YCVS) (Lederman, J., Bartels, Lederman, & Ganankkan, 2014). The YCVS assesses students' understandings of the aspects of scientific inquiry (SI) and the nature of science (NOS) that young elementary students are able to understand. These aspects are; science, scientists, multiple methods, observation/inference, begins with a question, empirical, subjectivity, tentativeness and creativity. The YCVS was administered orally for grade one students, and a paper-and-pencil version was given to grades three and five. Results indicated that there are very few gains in NOS and SI understandings between grades one and five in the schools included in this study. None of the schools in this study made significant gains for all of the nine aspects measured in this study. Examining curriculum's affect on NOS and SI understandings, understanding of only one aspect was significantly impacted by curriculum differences. Subjectivity understanding was impacted by kit-based instruction. Overall, students' understandings of science, scientists and how they do their work did not significantly change from grade one to grade five regardless of what type of curriculum they followed. This study shows that students' scientific literacy is not being developed throughout elementary school. Therefore, the teaching of scientific literacy in an explicit and reflective manner should be the focus of preservice elementary school education.

Mind-Body Connection on a High Wire: A Cross Disciplinary Ropes Course Experience for Graduate Students

ERIC Educational Resources Information Center

Graham, Louise B.; Robinson, Ellyn M.

2009-01-01

Two classes from diverse graduate programs merged and melded for a weeklong intensive outdoor experience to learn how to be leaders for an outdoor challenge course. Physical Education graduate students and students in a Counselor Education program together participated in the Challenge Course, co-led by an Exercise Scientist and a Psychologist.…

A motivational account of the undergraduate experience in science: brief measures of students' self-system appraisals, engagement in coursework, and identity as a scientist

NASA Astrophysics Data System (ADS)

Skinner, Ellen; Saxton, Emily; Currie, Cailin; Shusterman, Gwen

2017-11-01

As part of long-standing efforts to promote undergraduates' success in science, researchers have investigated the instructional strategies and motivational factors that promote student learning and persistence in science coursework and majors. This study aimed to create a set of brief measures that educators and researchers can use as tools to examine the undergraduate motivational experience in science classes. To identify key motivational processes, we drew on self-determination theory (SDT), which holds that students have fundamental needs - to feel competent, related, and autonomous - that fuel their intrinsic motivation. When educational experiences meet these needs, students engage more energetically and learn more, cumulatively contributing to a positive identity as a scientist. Based on information provided by 1013 students from 8 classes in biology, chemistry, and physics, we constructed conceptually focused and psychometrically sound survey measures of three sets of motivational factors: (1) students' appraisals of their own competence, autonomy, and relatedness; (2) the quality of students' behavioural and emotional engagement in academic work; and (3) students' emerging identities as scientists, including their science identity, purpose in science, and science career plans. Using an iterative confirmatory process, we tested short item sets for unidimensionality and internal consistency, and then cross-validated them. Tests of measurement invariance showed that scales were generally comparable across disciplines. Most importantly, scales and final course grades showed correlations consistent with predictions from SDT. These measures may provide a window on the student motivational experience for educators, researchers, and interventionists who aim to improve the quality of undergraduate science teaching and learning.

Modeling the Skills and Practices of Scientists through an “All-Inclusive” Comparative Planetology Student Research Investigation

NASA Technical Reports Server (NTRS)

Graff, Paige; Bandfield, J.; Stefanov, W.; Vanderbloemen, L.; Willis, K.; Runco, S.

2013-01-01

To effectively prepare the nation's future Science, Technology, Engineering, and Mathematics (STEM) workforce, students in today's classrooms need opportunities to engage in authentic experiences that model skills and practices used by STEM professionals. Relevant, real-world authentic research experiences allow students to behave as scientists as they model the process of science. This enables students to get a true sense of STEM-related professions and also allows them to develop the requisite knowledge, skills, curiosity, and creativity necessary for success in STEM careers. Providing professional development and opportunities to help teachers infuse research in the classroom is one of the primary goals of the Expedition Earth and Beyond (EEAB) program. EEAB, facilitated by the Astromaterials Research and Exploration Science (ARES) Directorate at the NASA Johnson Space Center, is an Earth and planetary science education program designed to inspire, engage, and educate teachers and students in grades 5-12 by getting them actively involved with exploration, discovery, and the process of science. The program combines the expertise of scientists and educators to ensure the professional development provided to classroom teachers is scientifically valid and also recognizes classroom constraints. For many teachers, facilitating research in the classroom can be challenging. In addition to addressing required academic standards and dealing with time constraints, challenges include structuring a research investigation the entire class can successfully complete. To build educator confidence, foster positive classroom research experiences, and enable teachers to help students model the skills and practices of scientists, EEAB has created an "allinclusive" comparative planetology research investigation activity. This activity addresses academic standards while recognizing students (and teachers) potentially lack experience with scientific practices involved in conducting research. Designed as an entry level research engagement investigation, the activity introduces, illustrates, and teaches the skills involved in each step of the research process. Students use astronaut photos, provided through the ARES Crew Earth Observations (CEO) payload on the International Space Station (ISS) as well as remote sensing imagery of other planetary worlds. By including all the necessary tools to complete the investigation, students can focus on gaining experience in the process of science. Additionally, students are able to extend their experience of modeling the skills and practices of scientists through the opportunity to request new data of Earth from the ISS. Professional development offered through in-person and webinar trainings, along with the resources provided, enable educators to gain first-hand experience implementing a structured research investigation in the classroom. Through data and feedback collected from teachers, this type of "all-inclusive" investigation activity aims to become a model that can be utilized for other research topics and STEM disciplines.

Modeling the Skills and Practices of Scientists through an 'All-Inclusive' Comparative Planetology Student Research Investigation

NASA Astrophysics Data System (ADS)

Graff, P. V.; Bandfield, J. L.; Stefanov, W. L.; Vanderbloemen, L.; Willis, K. J.; Runco, S.

2013-12-01

To effectively prepare the nation's future Science, Technology, Engineering, and Mathematics (STEM) workforce, students in today's classrooms need opportunities to engage in authentic experiences that model skills and practices used by STEM professionals. Relevant, real-world authentic research experiences allow students to behave as scientists as they model the process of science. This enables students to get a true sense of STEM-related professions and also allows them to develop the requisite knowledge, skills, curiosity, and creativity necessary for success in STEM careers. Providing professional development and opportunities to help teachers infuse research in the classroom is one of the primary goals of the Expedition Earth and Beyond (EEAB) program. EEAB, facilitated by the Astromaterials Research and Exploration Science (ARES) Directorate at the NASA Johnson Space Center, is an Earth and planetary science education program designed to inspire, engage, and educate teachers and students in grades 5-12 by getting them actively involved with exploration, discovery, and the process of science. The program combines the expertise of scientists and educators to ensure the professional development provided to classroom teachers is scientifically valid and also recognizes classroom constraints. For many teachers, facilitating research in the classroom can be challenging. In addition to addressing required academic standards and dealing with time constraints, challenges include structuring a research investigation the entire class can successfully complete. To build educator confidence, foster positive classroom research experiences, and enable teachers to help students model the skills and practices of scientists, EEAB has created an 'all-inclusive' comparative planetology research investigation activity. This activity addresses academic standards while recognizing students (and teachers) potentially lack experience with scientific practices involved in conducting research. Designed as an entry level research engagement investigation, the activity introduces, illustrates, and teaches the skills involved in each step of the research process. Students use astronaut photos, provided through the ARES Crew Earth Observations (CEO) payload on the International Space Station (ISS) as well as remote sensing imagery of other planetary worlds. By including all the necessary tools to complete the investigation, students can focus on gaining experience in the process of science. Additionally, students are able to extend their experience of modeling the skills and practices of scientists through the opportunity to request new data of Earth from the ISS. Professional development offered through in-person and webinar trainings, along with the resources provided, enable educators to gain first-hand experience implementing a structured research investigation in the classroom. Through data and feedback collected from teachers, this type of 'all-inclusive' investigation activity aims to become a model that can be utilized for other research topics and STEM disciplines.

Encouraging Teachers to Build Collaborations with Researchers; Examples From the Classroom (Invited)

NASA Astrophysics Data System (ADS)

Kane, M.

2013-12-01

Bringing experts into our schools allows for highly engaging lessons, encourages career thinking, adds authenticity to the topic, and allows student's questions to be answered by experts. Researchers can physically visit classrooms or appear through presentation technologies, such as Skype, or Google Hangouts. Virtual visits allow students to see laboratories and field sites. Collaborating with scientists builds the connective tissue that helps all educators and our students learn more deeply. When K-12 teachers collaborate with scientists and graduate students, teachers learn more science, and scientists learn more teaching. This growth of background knowledge is a win-win situation and helps us meet the expectations of the Common Core State Standards. Teachers need to feel encouraged to contact their local or regional scientists for support. Reaching out into the universities to make contact with polar scientists or graduate students is a good place to start. Building professional networks allows PI's to address the 'broader impact' requirement on many grant applications, and helps spread the university's work in the polar regions out to the general public. These collaborations also give teachers expert insights and current data to build authentic lessons, and excite their students to seek careers in the sciences. This presentation will focus on three completed interactive opportunities I have built with researchers in my classroom. Students adding daily sediment to their sediment core, after communications from the field with scientist Heidi Roop in Alaska.

Student-Generated Scientific Inquiry for Elementary Education Undergraduates: Course Development, Outcomes and Implications

ERIC Educational Resources Information Center

Salter, Irene; Atkins, Leslie

2013-01-01

While some researchers have argued for science classrooms that embrace open-inquiry by engaging students in doing science as scientists do (cf. National Research Council [NRC] 1996; Driver et al. in "Sci Educ" 84:287-312, 2000; Windschitl et al. in "Sci Educ" 87(1):112-143, 2008), others have argued that open-inquiry is impractical, ineffective,…

Who Believes in the Storybook Image of the Scientist?

PubMed

Veldkamp, Coosje L S; Hartgerink, Chris H J; van Assen, Marcel A L M; Wicherts, Jelte M

2017-01-01

Do lay people and scientists themselves recognize that scientists are human and therefore prone to human fallibilities such as error, bias, and even dishonesty? In a series of three experimental studies and one correlational study (total N = 3,278) we found that the "storybook image of the scientist" is pervasive: American lay people and scientists from over 60 countries attributed considerably more objectivity, rationality, open-mindedness, intelligence, integrity, and communality to scientists than to other highly-educated people. Moreover, scientists perceived even larger differences than lay people did. Some groups of scientists also differentiated between different categories of scientists: established scientists attributed higher levels of the scientific traits to established scientists than to early-career scientists and Ph.D. students, and higher levels to Ph.D. students than to early-career scientists. Female scientists attributed considerably higher levels of the scientific traits to female scientists than to male scientists. A strong belief in the storybook image and the (human) tendency to attribute higher levels of desirable traits to people in one's own group than to people in other groups may decrease scientists' willingness to adopt recently proposed practices to reduce error, bias and dishonesty in science.

Science Communication versus Science Education: The Graduate Student Scientist as a K-12 Classroom Resource

NASA Technical Reports Server (NTRS)

Strauss, Jeff; Shope, Richard E., III; Terebey, Susan

2005-01-01

Science literacy is a major goal of science educational reform (NRC, 1996; AAAS, 1998; NCLB Act, 2001). Some believe that teaching science only requires pedagogical content knowledge (PCK). Others believe doing science requires knowledge of the methodologies of scientific inquiry (NRC, 1996). With these two mindsets, the challenge for science educators is to create models that bring the two together. The common ground between those who teach science and those who do science is science communication, an interactive process that galvanizes dialogue among scientists, teachers, and learners in a rich ambience of mutual respect and a common, inclusive language of discourse . The dialogue between science and non-science is reflected in the polarization that separates those who do science and those who teach science, especially as it plays out everyday in the science classroom. You may be thinking, why is this important? It is vital because, although not all science learners become scientists, all K-12 students are expected to acquire science literacy, especially with the implementation of the No Child Left Behind Act of 2001 (NCLB). Students are expected to acquire the ability to follow the discourse of science as well as connect the world of science to the context of their everyday life if they plan on moving to the next grade level, and in some states, to graduate from high school. This paper posits that science communication is highly effective in providing the missing link for K-12 students cognition in science and their attainment of science literacy. This paper will focus on the "Science For Our Schools" (SFOS) model implemented at California State Univetsity, Los Angeles (CSULA) as a project of the National Science Foundation s GK-12 program, (NSF 2001) which has been a huge success in bridging the gap between those who "know" science and those who "teach" science. The SFOS model makes clear the distinctions that identify science, science communication, science education, and science literacy in the midst of science learning by bringing together graduate student scientists and science teachers to engage students in the two world s dialogue in the midst of the school science classroom. The graduate student scientists and the science teachers worked as a team throughout the school year and became effective science Communicators as they narrowed the gulf between the two worlds. 1

Inquiry-Driven Field-Based (IDFB) Ocean Science Classes: an Important Role in College Students' Development as Scientists, and Student Retention in the Geo-science Pipeline.

NASA Astrophysics Data System (ADS)

Crane, N. L.

2004-12-01

Experiential learning, engaging students in the process of science, can not only teach students important skills and knowledge, it can also help them become connected with the process on a personal level. This study investigates the role that Inquiry-Driven Field-Based (IDFB) experiences (primarily field classes) in ocean science have on undergraduate science students' development as ocean scientists. Both cognitive (knowledge-based) and affective (motivation and attitude) measures most important to students were used as indicators of development. Major themes will be presented to illustrate how IDFB science experiences can enhance the academic and personal development of students of science. Through their active engagement in the process of science, students gain important skills and knowledge as well as increased confidence, motivation, and ability to plan for their future (in particular their career and educational pathways). This growth is an important part of their development as scientists; the IDFB experience provides them a way to build a relationship with the world of science, and to better understand what science is, what scientists do, and their own future role as scientists. IDFB experiences have a particularly important role in affective measures of development: students develop an important personal connection to science. By doing science, students learn to be scientists and to understand science and science concepts in context. Many underrepresented students do not have the opportunity to take IDFB classes, and addressing this access issue could be an important step towards engaging more underrepresented students in the field. The nature of IDFB experiences and their impact on students makes them a potentially important mechanism for retaining students in the geo-science `pipeline'.

One More Legacy of Paul F. Brandwein: Creating Scientists

NASA Astrophysics Data System (ADS)

Fort, Deborah C.

2011-06-01

This paper studies the influence of Paul F. Brandwein, author, scientist, teacher and mentor, publisher, humanist, and environmentalist, on gifted youngsters who later became scientists, based primarily on information gathered from surveys completed by 25 of his students and one colleague. It also traces his profound interactions with science educators. It illuminates the theories of Brandwein and his protégés and colleagues about the interaction of environment, schooling, and education and Brandwein's belief in having students do original research (that is, research whose results are unknown) on their way to discovering their future scientific paths. It tests Brandwein's 1955 hypothesis on the characteristics typical of the young who eventually become scientists, namely: Three factors are considered as being significant in the development of future scientists: a Genetic Factor with a primary base in heredity (general intelligence, numerical ability, and verbal ability); a Predisposing Factor, with a primary base in functions which are psychological in nature; an Activating Factor, with a primary base in the opportunities offered in school and in the special skills of the teacher. High intelligence alone does not make a youngster a scientist (p xix).

Opportunities for Space Science Education Using Current and Future Solar System Missions

NASA Astrophysics Data System (ADS)

Matiella Novak, M.; Beisser, K.; Butler, L.; Turney, D.

2010-12-01

The Education and Public Outreach (E/PO) office in The Johns Hopkins University Applied Physics Laboratory (APL) Space Department strives to excite and inspire the next generation of explorers by creating interactive education experiences. Since 1959, APL engineers and scientists have designed, built, and launched 61 spacecraft and over 150 instruments involved in space science. With the vast array of current and future Solar System exploration missions available, endless opportunities exist for education programs to incorporate the real-world science of these missions. APL currently has numerous education and outreach programs tailored for K-12 formal and informal education, higher education, and general outreach communities. Current programs focus on Solar System exploration missions such as the Compact Reconnaissance Imaging Spectrometer for Mars (CRISM), Miniature Radio Frequency (Mini-RF) Moon explorer, the Radiation Belt Storm Probes (RBSP), New Horizons mission to Pluto, and the Thermosphere Ionosphere Mesosphere Energetics and Dynamics (TIMED) Satellite, to name a few. Education and outreach programs focusing on K-12 formal education include visits to classrooms, summer programs for middle school students, and teacher workshops. APL hosts a Girl Power event and a STEM (Science, Technology, Engineering, and Mathematics) Day each year. Education and outreach specialists hold teacher workshops throughout the year to train educators in using NASA spacecraft science in their lesson plans. High school students from around the U.S. are able to engage in NASA spacecraft science directly by participating in the Mars Exploration Student Data Teams (MESDT) and the Student Principal Investigator Programs. An effort is also made to generate excitement for future missions by focusing on what mysteries will be solved. Higher education programs are used to recruit and train the next generation of scientists and engineers. The NASA/APL Summer Internship Program offers a unique glimpse into the Space Department’s “end-to-end” approach to mission design and execution. College students - both undergraduate and graduate - are recruited from around the U.S. to work with APL scientists and engineers who act as mentors to the students. Many students are put on summer projects that allow them to work with existing spacecraft systems, while others participate in projects that investigate the operational and science objectives of future planned spacecraft systems. In many cases these interns have returned to APL as full-time staff after graduation.

Assessing the impact of Native American elders as co-educators for university students in STEM

NASA Astrophysics Data System (ADS)

Alkholy, Sarah Omar

Introduction: Minorities are underrepresented in the science, technology, engineering, and mathematics (STEM) workforce, post-secondary STEM education, and show high academic attrition rates. Academic performance and retention improve when culturally relevant support is provided. The interface of Western Science and Indigenous Science provides an opportunity for bridging this divide. This three parts project is an example of Community-based participatory research (CBPR) that aims to support academic institutions that serve minority students in STEM, and implement educational components (pedagogy) to serve the needs of the underserved community. Method: Part 1: was a cross-sectional used a survey given to participants designed to assess prevalence of natural health products use by students, and to determine how students learn about NHPs. Part 2: was a longitudinal survey pilot study based upon an online STEM course offer at four universities to determine the differences between U.S. vs. Canadian and minority vs. non-minority university students regarding their perceptions of traditional Elders as STEM co-educators, interest in STEM, and science identity by using a pre-and post- course survey. Part 3: was a longitudinal quasi-experiment based upon an online STEM course offered at four universities show what Indigenous science claims regarding: Elders are viewed as valuable STEM co-educators; Elders increase student interest in STEM; students exposed to Indigenous science improve their identity as a scientist; students exposed to Indigenous Science/Elders show improved learning outcomes. Result: We found that Native/Aboriginal students learn information about natural health products from traditional Elders significantly more so than non-Native/Aboriginal students. There were no statistically significant results from the pilot study. Findings from the quasi-experiment show that students taught with Indigenous science Elder co-educators have significantly greater interest in STEM than students not exposed to Elders' teachings. Minority students reported significantly less self-identification as a scientist than did White students at pre-course, but report similar identity as a scientist to White students post-course. Discussion: Future work should investigate the role of Elder traditional educators to convey NHPs information directed specifically to Aboriginal university students. We expect that Elder co-educators may then impact student science identity and interest in STEM. We expect that Elder co-educators may then impact student science identity and interest in STEM. Although there were no statistically significant results from the pilot study, the observed trends suggest that Indigenous science Elder educators merit involvement in novel pedagogical approaches and delivery modalities to reach minority students and to increase students' interest in STEM. From quasi-experiment we attribute these findings to the impact of culturally competent course content to minority students especially, in a post-secondary STEM class. This work establishes the need for convergence of Indigenous science and Western STEM in academia.

“Hidden” threats to science education

NASA Astrophysics Data System (ADS)

Huntoon, J. E.; Buchanan, R.; Buhr, S. M.; Kirst, S.; Newton, S.; Van Norden, W.

2012-04-01

Many readers of Eos are involved with education. Most would agree that what happens at precollege levels will ultimately affect the geoscience profession; after all, future scientists are today's precollege students. While a growing number of scientists are working to improve the quality of precollege programs, only a few are addressing what we term the "hidden" threats to science education. Hidden threats have nothing to do with scientific content; rather, they result from social, political, and bureaucratic forces operating within and outside of schools and universities.

A Scientist's Guide to Achieving Broader Impacts through K–12 STEM Collaboration

PubMed Central

Komoroske, Lisa M.; Hameed, Sarah O.; Szoboszlai, Amber I.; Newsom, Amanda J.; Williams, Susan L.

2015-01-01

The National Science Foundation and other funding agencies are increasingly requiring broader impacts in grant applications to encourage US scientists to contribute to science education and society. Concurrently, national science education standards are using more inquiry-based learning (IBL) to increase students’ capacity for abstract, conceptual thinking applicable to real-world problems. Scientists are particularly well suited to engage in broader impacts via science inquiry outreach, because scientific research is inherently an inquiry-based process. We provide a practical guide to help scientists overcome obstacles that inhibit their engagement in K–12 IBL outreach and to attain the accrued benefits. Strategies to overcome these challenges include scaling outreach projects to the time available, building collaborations in which scientists’ research overlaps with curriculum, employing backward planning to target specific learning objectives, encouraging scientists to share their passion, as well as their expertise with students, and transforming institutional incentives to support scientists engaging in educational outreach. PMID:26955078

Raising the Bar in Freshman Science Education: Student Lectures, Scientific Papers, and Independent Experiments

ERIC Educational Resources Information Center

Collins, Eva-Maria S.; Calhoun, Tessa R.

2014-01-01

This article presents the combination of three enhanced educational approaches for training future scientists. These methods incorporate skills generally not introduced in the freshman year: student-led blackboard introductions; the writing of scientific papers; and the design, execution, and presentation of an independent lab module. We tested…

Science and Me: A Student-Driven Science Outreach Program for Lay Adult Audiences

ERIC Educational Resources Information Center

Alexander, Hannah; Waldron, Anna M.; Abell, Sandra K.

2011-01-01

The increasing need for communicating science to the public suggests that future scientists and science educators should be educated in science outreach and trained to communicate with lay audiences. We present a recently developed novel graduate course, which trains students in outreach efforts aimed to increase the public's understanding of…

Middle and High School Students' Conceptions of Climate Change Mitigation and Adaptation Strategies

ERIC Educational Resources Information Center

Bofferding, Laura; Kloser, Matthew

2015-01-01

Both scientists and policy-makers emphasize the importance of education for influencing pro-environmental behavior and minimizing the effects of climate change on biological and physical systems. Education has the potential to impact students' system knowledge--their understanding of the variables that affect the climate system--and action…

Who Believes in the Storybook Image of the Scientist?

PubMed Central

Veldkamp, Coosje L. S.; Hartgerink, Chris H. J.; van Assen, Marcel A. L. M.; Wicherts, Jelte M.

2017-01-01

ABSTRACT Do lay people and scientists themselves recognize that scientists are human and therefore prone to human fallibilities such as error, bias, and even dishonesty? In a series of three experimental studies and one correlational study (total N = 3,278) we found that the “storybook image of the scientist” is pervasive: American lay people and scientists from over 60 countries attributed considerably more objectivity, rationality, open-mindedness, intelligence, integrity, and communality to scientists than to other highly-educated people. Moreover, scientists perceived even larger differences than lay people did. Some groups of scientists also differentiated between different categories of scientists: established scientists attributed higher levels of the scientific traits to established scientists than to early-career scientists and Ph.D. students, and higher levels to Ph.D. students than to early-career scientists. Female scientists attributed considerably higher levels of the scientific traits to female scientists than to male scientists. A strong belief in the storybook image and the (human) tendency to attribute higher levels of desirable traits to people in one’s own group than to people in other groups may decrease scientists’ willingness to adopt recently proposed practices to reduce error, bias and dishonesty in science. PMID:28001440

Scientists and Middle School Students; Learning and Working Together

NASA Astrophysics Data System (ADS)

Haste, T.

2007-12-01

Johns Hopkins University's Center for Talented Youth students enrolled in the Dynamic Earth class come from all over the world to study earth systems. Investigating plate action, crustal formation, glaciers, currents, weathering and atmospheric interactions, students develop a strong ability to identify the forces that continually change the landscape and the interconnectedness of the atmosphere, hydrosphere and lithosphere. As part of their regular course work, students work with a variety of cooperating scientists. US Geological Survey staff assists students in examining sand samples and exploring monitoring research on invasive foraminiferas in San Francisco Bay. Gulf of the Farallones National Marine Sanctuary and Mavericks Surf Ventures staff help students explore the off shore submarine formations of a storm swell at Half Moon Bay that develops into a world-class big wave. Students met a big wave surfer who described the ride and shared surf stories. A wave forecaster helped students use modeling software to create real-time forecasts. In the final project students assist faculty of University of Texas at Austin, Institute of Geophysics using cruise reports, project abstracts, and bathymetry images, in evaluating a series of submarine features in the Ross Sea, Antarctica. Students develop proposals and present their ideas in a seminar format, attended by cooperating scientists. Students have an opportunity to work with current scientists and learn how classroom "stuff" is used. One student commented, "I felt like I could talk with them about what they were doing and actually understand what they were talking about." Another stated, "I didn't know you could learn so much from forams. I always thought paleontology was about dinosaurs." As a result of the class, students understand the relevance of their learning, scientists like working with kids, and educators get excited about science. To evaluate program outcomes, the staff holds regular meetings with scientists as students begin the sessions. Faculty and scientists work collaboratively to develop activities students will be engaged in and that relates to the scientists' work. Students and faculty complete evaluations. A report is generated at the close of the summer outlining plans for the next season, detailing successes, and areas of improvement.

More Than Just Chemistry: The Impact of a Collaborative Participant Structure on Student Perceptions of Science

NASA Astrophysics Data System (ADS)

Patchen, Terri; Smithenry, Dennis W.

2015-02-01

Researchers have theorized that integrating authentic science activities into classrooms will help students learn how working scientists collaboratively construct knowledge, but few empirical studies have examined students' experiences with these types of activities. Utilizing data from a comparative, mixed-methods study, we considered how integrating a complex, collaborative participant structure into a secondary school chemistry curriculum shapes students' perceptions of what constitutes "science." We found that the implementation of this participant structure expanded student perceptions of chemistry learning beyond the typical focus on science content knowledge to include the acquisition of collaboration skills. This support for the collaborative construction of knowledge, in addition to the appropriation of scientific content, establishes the conditions for what science educators and scientists say they want: students who can work together to solve science problems. Radical shifts towards such collaborative participant structures are necessary if we are to modify student perceptions of science and science classrooms in ways that are aligned with recent calls for science education reform.

Global Climate Models for the Classroom: The Educational Impact of Student Work with a Key Tool of Climate Scientists

NASA Astrophysics Data System (ADS)

Bush, D. F.; Sieber, R.; Seiler, G.; Chandler, M. A.; Chmura, G. L.

2017-12-01

Efforts to address climate change require public understanding of Earth and climate science. To meet this need, educators require instructional approaches and scientific technologies that overcome cultural barriers to impart conceptual understanding of the work of climate scientists. We compared student inquiry learning with now ubiquitous climate education toy models, data and tools against that which took place using a computational global climate model (GCM) from the National Aeronautics and Space Administration (NASA). Our study at McGill University and John Abbott College in Montreal, QC sheds light on how best to teach the research processes important to Earth and climate scientists studying atmospheric and Earth system processes but ill-understood by those outside the scientific community. We followed a pre/post, control/treatment experimental design that enabled detailed analysis and statistically significant results. Our research found more students succeed at understanding climate change when exposed to actual climate research processes and instruments. Inquiry-based education with a GCM resulted in significantly higher scores pre to post on diagnostic exams (quantitatively) and more complete conceptual understandings (qualitatively). We recognize the difficulty in planning and teaching inquiry with complex technology and we also found evidence that lectures support learning geared toward assessment exams.

The Benefits of Being a Student of Teacher Researchers Experiences (sotre)

NASA Astrophysics Data System (ADS)

Eubanks, E.; Guinan, E.; Chiste, M.; Lavoie, A.

2016-02-01

Being a Student of Teacher Researcher Experiences (SoTRE), gets students excited for science. Eubanks brings real, current science to the classroom because of time spent in Teacher Researcher Experiences (TRE), where she works with researchers in and out of the field. She involves students in many programs including the National Oceanographic and Atmospheric Administration (NOAA), Polar TREC (Teachers and Researchers & Exploring & Collaboration), National Science Foundation (NSF) funded researchers, (EARTH) Education and Research: Testing Hypothesis, the RJ Dunlap Marine Conservation Program, C-DEBI (Center for Dark Energy Biosphere Investigations and (STARS) Sending Teachers Aboard Research Ships. Being in these programs gives students special privileges such as understanding unique research ideas, tracking tagged sharks, following daily journals written on location, taking part in cross-continental experiments, tracking real time data, exploring current research via posters or visiting universities. Furthermore, contacts made by a TRE give students an added set of resources. When doing experiments for class or advancing their education or career goals, Mrs. Eubanks helps students connect with scientists. This gives students a unique opportunity to learn from real scientists. Being part of these relationships with NOAA, Polar TREC, EARTH, RJ Dunlap, STARS and NSF funded scientists who are actively working, makes being SoTRE the ultimate learning experience. Many students have felt so strongly about the TRE relationship that they have presented at several local and international science conferences. Their message is to encourage scientists to partner with teachers. The benefits of participation in such conferences have included abstract writing and submission, travel, poster creation, networking and presentation, all tools that they will carry with them for a lifetime.

Educating Students on the Need to Protect Authentic Science in Public Policy

NASA Astrophysics Data System (ADS)

Grifo, F.; McCarthy, M.; Langlais, C.

2008-12-01

Scientists have an important responsibility to be sure their students are aware of the ways in which their research results can be politicized and misused. Political interference in science has penetrated deeply into the culture and practices of federal agencies. The persistent and energetic engagement of scientists is critical to ensuring the government meets its obligation to serve the public interest. To foster thoughtful discussions about the proper role of science in federal policy making, the Union of Concerned Scientists (UCS) has created a Scientific Integrity Curriculum Guide to help graduate, undergraduate and advanced high school instructors teach this complex subject. The guide is a fully developed lesson plan that teachers in both scientific and non-scientific disciplines can tailor to suit their needs. It provides lecture slides, worksheets, homework assignments, essay suggestions, and links to other resources. Educating the next generation of scientists is essential because significant and long-lasting reforms require the support of a well- informed scientific community.

Current Crisis in Science Education? Women in Science and Problems for the Behavioral Scientists. Some Perspectives of a Physicist.

ERIC Educational Resources Information Center

Dresselhaus, Mildred S.

A number of problems exist in society which require the cooperation of physical and social scientists. One of these problems is the current crisis in science education. There are several aspects to this problem, including the declining interest of students in math and science at a time when functioning in our society requires more, not less,…

Scientists in the Classroom Mentor Model Program - Bringing real time science into the K - 12 classroom

NASA Astrophysics Data System (ADS)

Worssam, J. B.

2017-12-01

Field research finally within classroom walls, data driven, hands on with students using a series of electronic projects to show evidence of scientific mentor collaboration. You do not want to miss this session in which I will be sharing the steps to develop an interactive mentor program between scientists in the field and students in the classroom. Using next generation science standards and common core language skills you will be able to blend scientific exploration with scientific writing and communication skills. Learn how to make connections in your own community with STEM businesses, agencies and organizations. Learn how to connect with scientists across the globe to make your classroom instruction interactive and live for all students. Scientists, you too will want to participate, see how you can reach out and be a part of the K-12 educational system with students learning about YOUR science, a great component for NSF grants! "Scientists in the Classroom," a model program for all, bringing real time science, data and knowledge into the classroom.

Making Climate Hot: Preparing Scientists and Teachers for Climate Change Communication and Education

NASA Astrophysics Data System (ADS)

Buhr, S. M.; Wise, S. B.

2008-05-01

Anyone having anything to do with climate change science (or even geosciences) is increasingly asked to communicate about climate change with friends and family, media, the general public, and students. But, we have often not had the training to communicate with simplicity and clarity about such a complex topic. Furthermore, the need to know how to accommodate controversy, common misconceptions, and contrarian arguments complicates the task. The CIRES Education and Outreach group has developed a short professional development workshop "Making Climate Hot: How to Communicate Effectively about Climate Change". The goals of the workshop are to make scientists and educators aware of best practices in climate change communications, provide some tools for crafting messages, and allow participants to practice skills in a supportive, low-risk environment. The "Making Climate Hot" workshop has been piloted with scientists and university communicators, teachers and environmental educators and college students anxious to communicate with family and roommates. The most and least effective aspects of the workshop will be described, along with the lessons learned and next steps.

Uncovering Scientist Stereotypes and Their Relationships with Student Race and Student Success in a Diverse, Community College Setting.

PubMed

Schinske, Jeffrey; Cardenas, Monica; Kaliangara, Jahana

2015-01-01

A number of studies have identified correlations between children's stereotypes of scientists, their science identities, and interest or persistence in science, technology, engineering, and mathematics. Yet relatively few studies have examined scientist stereotypes among college students, and the literature regarding these issues in predominantly nonwhite and 2-yr college settings is especially sparse. We piloted an easy-to-analyze qualitative survey of scientist stereotypes in a biology class at a diverse, 2-yr, Asian American and Native American Pacific Islander-Serving Institution. We examined the reliability and validity of the survey, and characterized students' comments with reference to previous research on stereotypes. Positive scientist stereotypes were relatively common in our sample, and negative stereotypes were rare. Negative stereotypes appeared to be concentrated within certain demographic groups. We found that students identifying nonstereotypical images of scientists at the start of class had higher rates of success in the course than their counterparts. Finally, evidence suggested many students lacked knowledge of actual scientists, such that they had few real-world reference points to inform their stereotypes of scientists. This study augments the scant literature regarding scientist stereotypes in diverse college settings and provides insights for future efforts to address stereotype threat and science identity. © 2015 J. Schinske 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).

NASA and Earth Science Week: a Model for Engaging Scientists and Engineers in Education and Outreach

NASA Astrophysics Data System (ADS)

Schwerin, T. G.; deCharon, A.; Brown de Colstoun, E. C.; Chambers, L. H.; Woroner, M.; Taylor, J.; Callery, S.; Jackson, R.; Riebeek, H.; Butcher, G. J.

2014-12-01

Earth Science Week (ESW) - the 2nd full week in October - is a national and international event to help the public, particularly educators and students, gain a better understanding and appreciation for the Earth sciences. The American Geosciences Institute (AGI) organizes ESW, along with partners including NASA, using annual themes (e.g., the theme for 2014 is Earth's Connected Systems). ESW provides a unique opportunity for NASA scientists and engineers across multiple missions and projects to share NASA STEM, their personal stories and enthusiasm to engage and inspire the next generation of Earth explorers. Over the past five years, NASA's ESW campaign has been planned and implemented by a cross-mission/cross-project group, led by the NASA Earth Science Education and Pubic Outreach Forum, and utilizing a wide range of media and approaches (including both English- and Spanish-language events and content) to deliver NASA STEM to teachers and students. These included webcasts, social media (blogs, twitter chats, Google+ hangouts, Reddit Ask Me Anything), videos, printed and online resources, and local events and visits to classrooms. Dozens of NASA scientists, engineers, and communication and education specialists contribute and participate each year. This presentation will provide more information about this activity and offer suggestions and advice for others engaging scientists and engineers in education and outreach programs and events.

Students, Teachers, and Scientists Partner to Explore Mars

NASA Astrophysics Data System (ADS)

Bowman, C. D.; Bebak, M.; Curtis, K.; Daniel, C.; Grigsby, B.; Herman, T.; Haynes, E.; Lineberger, D. H.; Pieruccini, S.; Ransom, S.; Reedy, K.; Spencer, C.; Steege, A.

2003-12-01

The Mars Exploration Rovers began their journey to the red planet in the summer of 2003 and, in early 2004, will begin an unprecedented level of scientific exploration on Mars, attracting the attention of scientists and the public worldwide. In an effort to engage students and teachers in this exciting endeavor, NASA's Mars Public Engagement Office, partnering with the Athena Science Investigation, coordinates a student-scientist research partnership program called the Athena Student Interns Program. The Athena Student Interns Program \\(ASIP\\) began in early 1999 as the LAPIS program, a pilot hands-on educational effort associated with the FIDO prototype Mars rover field tests \\(Arvidson, 2000\\). In ASIP, small groups of students and teachers selected through a national application process are paired with mentors from the mission's Athena Science Team to carry out an aspect of the mission. To prepare for actual operations during the landed rover mission, the students and teachers participate in one of the Science Team's Operational Readiness Tests \\(ORTs\\) at JPL using a prototype rover in a simulated Mars environment \\(Crisp, et al., in press. See also http://mars.jpl.nasa.gov/mer/fido/\\). Once the rovers have landed, each ASIP group will spend one week at JPL in mission operations, working as part of their mentor's own team to help manage and interpret data coming from Mars. To reach other teachers and students, each group gives school and community presentations, contributes to publications such as web articles and conference abstracts, and participates in NASA webcasts and webchats. Partnering with other groups and organizations, such as NASA's Solar System Ambassadors and the Housing and Urban Development Neighborhood Networks helps reach an even broader audience. ASIP is evaluated through the use of empowerment evaluation, a technique that actively involves participants in program assessment \\(Fetterman and Bowman, 2002\\). With the knowledge they gain through the ASIP program and their participation in the empowerment evaluation, ASIP members will help refine the current program and provide a model for student-scientist research partnerships associated with future space missions to Mars and beyond. Arvidson, R.E., et al. \\(2000\\) Students participate in Mars Sample Return Rover field tests. Eos, 81(11). Crisp, J.A., et al. \\(in press\\) The Mars Exploration Rover Mission. J. Geophys. Research-Planets. Fetterman, D. and C.D. Bowman. \\(2002\\) Experiential Education and Empowerment Evaluation: Mars Rover Educational Program Case Example. J. Experiential Education, 25(2).

A Comparative Study on Scientific Misconduct between Korean and Japanese Science Gifted Students

ERIC Educational Resources Information Center

Lee, Jiwon; Kim, Jung Bog; Isozaki, Tetsuo

2017-01-01

The scientific integrity, perceptions of scientific misconduct, and students' needs in the research ethics education of Korean and Japanese gifted students were analyzed to address three questions. First, how well do students practice research ethics in their research? Second, how do students perceive scientists' misconduct? Third, do students…

Key Words in Instruction. The Student Information Scientist, Part I

ERIC Educational Resources Information Center

Callison, Daniel

2005-01-01

Information literacy standards for student learning, indicators for student performance, and hundreds of collaborative lesson plans around the country give some indication of the skills students are expected to master as effective and efficient users of information. Hopefully the goal is that all involved in information literacy education become…

Real Science, Real Learning: Bridging the Gap Between Scientists, Educators and Students

NASA Astrophysics Data System (ADS)

Lewis, Y.

2006-05-01

Today as never before, America needs its citizens to be literate in science and technology. Not only must we only inspire a new generation of scientists and engineers and technologists, we must foster a society capable of meeting complex, 21st-century challenges. Unfortunately, the need for creative, flexible thinkers is growing at a time when our young students are lagging in science interest and performance. Over the past 17 years, the JASON Project has worked to link real science and scientists to the classroom. This link provide viable pipeline to creating the next generation scientists and researchers. Ultimately, JASON's mission is to improve the way science is taught by enabling students to learn directly from leading scientists. Through partnerships with agencies such as NOAA and NASA, JASON creates multimedia classroom products based on current scientific research. Broadcasts of science expeditions, hosted by leading researchers, are coupled with classroom materials that include interactive computer-based simulations, video- on-demand, inquiry-based experiments and activities, and print materials for students and teachers. A "gated" Web site hosts online resources and provides a secure platform to network with scientists and other classrooms in a nationwide community of learners. Each curriculum is organized around a specific theme for a comprehensive learning experience. It may be taught as a complete package, or individual components can be selected to teach specific, standards-based concepts. Such thematic units include: Disappearing Wetlands, Mysteries of Earth and Mars, and Monster Storms. All JASON curriculum units are grounded in "inquiry-based learning." The highly interactive curriculum will enable students to access current, real-world scientific research and employ the scientific method through reflection, investigation, identification of problems, sharing of data, and forming and testing hypotheses. JASON specializes in effectively applying technology in science education by designing animated interactive visualizations that promote student understanding of complex scientific concepts and systems (Rieber, 1990, 1996). JASON's experience in utilizing the power of simulation technology has been widely recognized for its effectiveness in exciting and engaging students in science learning by independent evaluations of JASON's multimedia science curriculum (Ba et al., 2001; Goldenberg et al., 2003). The data collected indicates that JASON's science products have had a positive impact on students' science learning, have positively influenced their perceptions of scientists and of becoming scientists, and have helped diverse students grasp a deeper understanding of complex scientific content, concepts and technologies.

Professionals and Emerging Scientists Sharing Science

NASA Technical Reports Server (NTRS)

Graff, P. V.; Allen, J. S.; Tobola, K.

2010-01-01

The Year of the Solar System (YSS) celebration begins in the fall of 2010. As YSS provides a means in which NASA can inspire members of the public about exciting missions to other worlds in our solar system, it is important to remember these missions are about the science being conducted and new discoveries being made. As part of the Year of the Solar System, Astromaterials Research and Exploration Science (ARES) Education, at the NASA Johnson Space Center, will infuse the great YSS celebration within the Expedition Earth and Beyond Program. Expedition Earth and Beyond (EEAB) is an authentic research program for students in grades 5-14 and is a component of ARES Education. Students involved in EEAB have the opportunity to conduct and share their research about Earth and/or planetary comparisons. ARES Education will help celebrate this exciting Year of the Solar System by inviting scientists to share their science. Throughout YSS, each month will highlight a topic related to exploring our solar system. Additionally, special mission events will be highlighted to increase awareness of the exciting missions and exploration milestones. To bring this excitement to classrooms across the nation, the Expedition Earth and Beyond Program and ARES Education will host classroom connection events in which scientists will have an opportunity to share discoveries being made through scientific research that relate to the YSS topic of the month. These interactive presentations will immerse students in some of the realities of exploration and potentially inspire them to conduct their own investigations. Additionally, scientists will share their own story of how they were inspired to pursue a STEM-related career that got them involved in exploration. These career highlights will allow students to understand and relate to the different avenues that scientists have taken to get where they are today. To bring the sharing of science full circle, student groups who conduct research by participating in Expedition Earth and Beyond, will also have the opportunity to virtually share their research. These virtual team presentations will allow these emerging scientists to celebrate their own exploration, and in doing so, contribute to the excitement of the Year of the Solar System. As the public joins NASA in the celebration of YSS, students across the nation will not only be excited by the science and discoveries being made, but will prime themselves with experience to perhaps someday become the new leaders in science, discovery, and NASA.

Processes and Procedures of the Higher Education Programs at Marshall Space Flight Center

NASA Technical Reports Server (NTRS)

Heard, Pamala D.

2002-01-01

The purpose of my research was to investigate the policies, processes, procedures and timelines for the higher education programs at Marshall Space Flight Center. The three higher education programs that comprised this research included: the Graduate Student Researchers Program (GSRP), the National Research Council/Resident Research Associateships Program (NRC/RRA) and the Summer Faculty Fellowship Program (SFFP). The GSRP award fellowships each year to promising U.S. graduate students whose research interest coincides with NASA's mission. Fellowships are awarded for one year and are renewable for up to three years to competitively selected students. Each year, the award provides students the opportunity to spend a period in residence at a NASA center using that installation's unique facilities. This program is renewable for three years, students must reapply. The National Research Council conducts the Resident Research Associateships Program (NRC/RRA), a national competition to identify outstanding recent postdoctoral scientists and engineers and experience senior scientists and engineers, for tenure as guest researchers at NASA centers. The Resident Research Associateship Program provides an opportunity for recipients of doctoral degrees to concentrate their research in association with NASA personnel, often as a culmination to formal career preparation. The program also affords established scientists and engineers an opportunity for research without any interruptions and distracting assignments generated from permanent career positions. All opportunities for research at NASA Centers are open to citizens of the U.S. and to legal permanent residents. The Summer Faculty Fellowship Program (SFFP) is conducted each summer. NASA awards research fellowships to university faculty through the NASA/American Society for Engineering Education. The program is designed to promote an exchange of ideas between university faculties, NASA scientists and engineers. Selected participants in fields of science, engineering, math, and other disciplines spend approximately 10 weeks working with their professional peers on research projects at NASA facilities. Workshops and seminars further enrich the experience. This program is only for U.S. citizens.

Student Scientific Research within Communities-of-Practice (Abstract)

NASA Astrophysics Data System (ADS)

Genet, R.; Armstrong, J.; Blanko, P.; Boyce, G. B. P.; Brewer, M.; Buchheim, R.; Calanog, J.; Castaneda, D.; Chamberlin, R.; Clark, R. K.; Collins, D.; Conti, D.; Cormier, S.; FItzgerald, M.; Estrada, C.; Estrada, R.; Freed, R.; Gomez, E.; Hardersen, P.; Harshaw, R.; Johnson, J.; Kafka, S.; Kenney, J.; Monanan, K.; Ridgely, J.; Rowe, D.; Silliman, M.; Stojimirovic, I.; Tock, K.; Walker, D.

2017-12-01

(Abstract only) Social learning theory suggests that students who wish to become scientists will benefit by being active researchers early in their educational careers. As coauthors of published research, they identify themselves as scientists. This provides them with the inspiration, motivation, and staying power that many will need to complete the long educational process. This hypothesis was put to the test over the past decade by a one-semester astronomy research seminar where teams of students managed their own research. Well over a hundred published papers coauthored by high school and undergraduate students at a handful of schools substantiated this hypothesis. However, one could argue that this was a special case. Astronomy, after all, is supported by a large professional-amateur community-of-practice. Furthermore, the specific area of research - double star astrometry - was chosen because the observations could be quickly made, the data reduction and analysis was straight forward, and publication of the research was welcomed by the Journal of Double Star Observations. A recently initiated seminar development and expansion program - supported in part by the National Science Foundation - is testing a more general hypothesis that: (1) the seminar can be successfully adopted by many other schools; (2) research within astronomy can be extended from double star astrometry to time series photometry of variable stars, exoplanet transits, and asteroids; and (3) the seminar model can be extended to a science beyond astronomy: environmental science' specifically atmospheric science. If the more general hypothesis is also supported, seminars that similarly feature published high school and undergraduate student team research could have the potential to significantly improve science education by increasing the percentage of students who complete the education required to become professional scientists.

Student Scientific Research within Communities-of-Practice

NASA Astrophysics Data System (ADS)

Genet, Russell; Armstrong, James; Blanko, Philip; Boyce, Grady Boyce, Pat; Brewer, Mark; Buchheim, Robert; Calanog, Jae; Castaneda, Diana; Chamberlin, Rebecca; Clark, R. Kent; Collins, Dwight; Conti, Dennis Cormier, Sebastien; Fitzgerald, Michael; Estrada, Chris; Estrada, Reed; Freed, Rachel Gomez, Edward; Hardersen, Paul; Harshaw, Richard; Johnson, Jolyon Kafka, Stella; Kenney, John; Mohanan, Kakkala; Ridgely, John; Rowe, David Silliman, Mark; Stojimirovic, Irena; Tock, Kalee; Walker, Douglas; Wallen, Vera

2017-06-01

Social learning theory suggests that students who wish to become scientists will benefit by being active researchers early in their educational careers. As coauthors of published research, they identify themselves as scientists. This provides them with the inspiration, motivation, and staying power that many will need to complete the long educational process. This hypothesis was put to the test over the past decade by a one-semester astronomy research seminar where teams of students managed their own research. Well over a hundred published papers coauthored by high school and undergraduate students at a handful of schools substantiated this hypothesis. However, one could argue that this was a special case. Astronomy, after all, is supported by a large professional-amateur community-of-practice. Furthermore, the specific area of research-double star astrometry-was chosen because the observations could be quickly made, the data reduction and analysis was straight forward, and publication of the research was welcomed by the Journal of Double Star Observations. A recently initiated seminar development and expansion program-supported in part by the National Science Foundation-is testing a more general hypothesis that: (1) the seminar can be successfully adopted by many other schools; (2) research within astronomy can be extended from double star astrometry to time series photometry of variable stars, exoplanet transits, and asteroids; and (3) the seminar model can be extended to a science beyond astronomy: environmental science-specifically atmospheric science. If the more general hypothesis is also supported, seminars that similarly feature published high school and undergraduate student team research could have the potential to significantly improve science education by increasing the percentage of students who complete the education required to become professional scientists.

Using existing programs as vehicles to disseminate knowledge, provide opportunities for scientists to assist educators, and to engage students in using real data

NASA Astrophysics Data System (ADS)

Smith, S. C.; Wegner, K.; Branch, B. D.; Miller, B.; Schulze, D. G.

2013-12-01

Many national and statewide programs throughout the K-12 science education environment teach students about science in a hands-on format, including programs such as Global Learning and Observations to Benefit the Environment (GLOBE), Project Learning Tree (PLT), Project Wild, Project Wet, and Hoosier River Watch. Partnering with one or more of these well-known programs can provide many benefits to both the scientists involved in disseminating research and the K-12 educators. Scientists potentially benefit by broader dissemination of their research by providing content enrichment for educators. Educators benefit by gaining understanding in content, becoming more confident in teaching the concept, and increasing their enthusiasm in teaching the concepts addressed. This presentation will discuss an innovative framework for professional development that was implemented at Purdue University, Indiana in July 2013. The professional development incorporated GLOBE protocols with iPad app modules and interactive content sessions from faculty and professionals. By collaborating with the GLOBE program and scientists from various content areas, the Department of Earth, Atmospheric, and Planetary Sciences at Purdue University successfully facilitated a content rich learning experience for educators. Such activity is promoted and supported by Purdue University Libraries where activities such as Purdue's GIS Day are efforts of making authentic learning sustainable in the State of Indiana and for national consideration. Using iPads to visualize soil transitions on a field trip. Testing Water quality in the field.

Understanding the Greenhouse Effect by Embodiment - Analysing and Using Students' and Scientists' Conceptual Resources

NASA Astrophysics Data System (ADS)

Niebert, Kai; Gropengießer, Harald

2014-01-01

Over the last 20 years, science education studies have reported that there are very different understandings among students of science regarding the key aspects of climate change. We used the cognitive linguistic framework of experientialism to shed new light on this valuable pool of studies to identify the conceptual resources of understanding climate change. In our study, we interviewed 35 secondary school students on their understanding of the greenhouse effect and analysed the conceptions of climate scientists as drawn from textbooks and research reports. We analysed all data by metaphor analysis and qualitative content analysis to gain insight into students' and scientists' resources for understanding. In our analysis, we found that students and scientists refer to the same schemata to understand the greenhouse effect. We categorised their conceptions into three different principles the conceptions are based on: warming by more input, warming by less output, and warming by a new equilibrium. By interrelating students' and scientists' conceptions, we identified the students' learning demand: First, our students were afforded with experiences regarding the interactions of electromagnetic radiation and CO2. Second, our students reflected about the experience-based schemata they use as source domains for metaphorical understanding of the greenhouse effect. By uncovering the-mostly unconscious-deployed schemata, we gave students access to their source domains. We implemented these teaching guidelines in interventions and evaluated them in teaching experiments to develop evidence-based and theory-guided learning activities on the greenhouse effect.

Scientist Spotlight Homework Assignments Shift Students' Stereotypes of Scientists and Enhance Science Identity in a Diverse Introductory Science Class.

PubMed

Schinske, Jeffrey N; Perkins, Heather; Snyder, Amanda; Wyer, Mary

2016-01-01

Research into science identity, stereotype threat, and possible selves suggests a lack of diverse representations of scientists could impede traditionally underserved students from persisting and succeeding in science. We evaluated a series of metacognitive homework assignments ("Scientist Spotlights") that featured counterstereotypical examples of scientists in an introductory biology class at a diverse community college. Scientist Spotlights additionally served as tools for content coverage, as scientists were selected to match topics covered each week. We analyzed beginning- and end-of-course essays completed by students during each of five courses with Scientist Spotlights and two courses with equivalent homework assignments that lacked connections to the stories of diverse scientists. Students completing Scientist Spotlights shifted toward counterstereotypical descriptions of scientists and conveyed an enhanced ability to personally relate to scientists following the intervention. Longitudinal data suggested these shifts were maintained 6 months after the completion of the course. Analyses further uncovered correlations between these shifts, interest in science, and course grades. As Scientist Spotlights require very little class time and complement existing curricula, they represent a promising tool for enhancing science identity, shifting stereotypes, and connecting content to issues of equity and diversity in a broad range of STEM classrooms. © 2016 J. N. Schinske et al. CBE—Life Sciences Education © 2016 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).

Scientist in the Classroom: Highlights of a Plasma Outreach Program

NASA Astrophysics Data System (ADS)

Nagy, A.; Lee, R. L.

2000-10-01

The General Atomics education program ``Scientist in the Classroom'' now in its third year, uses scientists and engineers to present ``Plasma the fourth state of matter,'' to students in the classroom. A program goal is to make science an enjoyable experience while showing students how plasma plays an important role in their world. A fusion overview is presented, including topics on energy and environment. Using hands-on equipment, students manipulate a plasma discharge using magnets, observe its spectral properties and observe the plasma in a fluorescent tube. In addition, they observe physical properties of liquid nitrogen, and use an infrared camera to observe radiant heat energy. Several program benefits are; it costs less than facility tours, is more flexible in scheduling, and is adaptable for grades 2--adult. The program has doubled in coverage since last year, with over 2200 students at 20 schools visited by 8 scientists. Increased participation by the DIII-D staff in this program has been achieved by enlisting them to bring the program to their children's school.

Using partnerships with scientists to enhance teacher capacity to address the NGSS

NASA Astrophysics Data System (ADS)

Pavelsky, T.; Haine, D. B.; Drostin, M.

2013-12-01

Increasingly, scientists are seeking outreach experts to assist with the education and outreach components of their research grants. These experts have the skills and expertise to assist with translating scientific research into lessons and activities that are aligned to the Next Generation Science Standards (NGSS) as well as state standards, are STEM-focused and that address the realities of the K-12 science classroom. Since 2007, the Institute for the Environment (IE) at the University of North Carolina at Chapel Hill has been conducting teacher professional development and high school student science enrichment programs to promote climate literacy. Partnering with scientists to deepen content knowledge and promote engagement with technology and real data has been a successful strategy for cultivating increased climate literacy among teachers and students. In this session, we will share strategies for effectively engaging scientists in K-12 educational activities by providing specific examples of the various ways in which scientists can be integrated into programming and their research translated into relevant classroom activities. Engaging scientists and translating their research into classroom activities is an approach that becomes even more relevant with the advent of the NGSS. The NGSS's Disciplinary Core Ideas (DCIs) that encompass climate literacy can be addressed by partnering with scientists to provide teachers with current content knowledge and technological tools needed to promote integration of relevant science and engineering practices and cross-cutting themes. Here we highlight a successful partnership in which IE science educators collaborated with with a faculty member to develop a lesson for North Carolina teachers introducing them to new research on satellite remote sensing of the water cycle, while also promoting student engagement with local data. The resulting lesson was featured during a two-day, IE-led teacher workshop for 21 North Carolina high school teachers in July 2013 titled, 'Observing regional and global water resources: Using remote sensing and field data to better understand the hydrologic cycle.'

Bringing Exoplanet Habitability Investigations to High School

NASA Astrophysics Data System (ADS)

Woody, M. A.; Sohl, L. E.

2016-12-01

Habitability, a.k.a. habitat suitability, is a topic typically discussed in Biology class. We present here a curriculum unit that introduces the topic in a Physics classroom, allowing students to engage in cutting-edge science and re-framing an otherwise "typical" unit. Unit development was made possible by the Climate Change Research Initiative (CCRI) at the NASA Goddard Institute for Space Studies, a year-long program that partners a scientist-mentor with a high school educator to engage in research and curriculum development. At its core, habitability is a temperature-dependent quality that is introduced and explored during the Energy unit. Students conducted a research project with the goal of determining the habitability state for a chosen exoplanet. Classroom implementation was modeled after the scientist-mentor's actual research plan, with content and resources for lesson activities also contributed by the scientist. Students first engaged in discussion of 5 basic habitability factors and explored these variables through climate modeling software. Students then chose an exoplanet to examine through the lens of those habitability factors, an activity that required them to perform authentic research on the exoplanet and its host star. Students also developed hypotheses about factors beyond currently available mission data, such as atmospheric composition and surface albedo of their exoplanet. They then used the modeling software to collect data, test hypotheses, and draw conclusions. Lastly, students communicated their findings in a poster session and presentation at the high school's annual science symposium. This scientist/educator partnership had a strongly positive impact on the high school students involved. By bringing actual science and research practices to the classroom, the students were not only more actively engaged with the required Physics course content, but also gained a better understanding of how scientific research is done.

Storm Peak Laboratory 5th-6th Grade Climate and Weather Program

NASA Astrophysics Data System (ADS)

McCubbin, I. B.; Hallar, A. G.

2008-12-01

Storm Peak Laboratory (SPL) has created a place-based elementary school program, which has been implemented at five elementary schools in Northwest Colorado. Real understanding, not factual recall, is the primary goal and developing a desire to be lifelong learners in science is a secondary goal. The specific objectives of the program include the following: 1) Develop a weather and climate curriculum that teaches skills required by Colorado Student Assessment Program (CSAP). 2) Provide a hands-on place-based educational experience where students have an opportunity to use scientific equipment. 3) Provide students a three-day program that consists of an introduction, field program, and follow-up to help students grasp concepts and apply them to other school studies. 4) Provide all participating students with understanding of climate and weather 5) Build foundations for students to understand climate change. 6) Disseminate to alpine regions across the Western US, potentially impacting thousands of students that will experience the impacts of climate change during their lifetime. The SPL program spans three days for each school and includes five elementary schools. During the first day, a scientist and educators from SPL visit each classroom for two hours to introduce the concepts of climate and weather as well as teach students how to use scientific equipment. During the field program on the second day, students measure and record information about temperature, pressure, relative humidity, wind speed, and particle concentration while they travel to SPL via the gondola and chair lifts (in winter) or 4WD Suburbans (in fall). Once at the laboratory, students will meet with both SPL scientists and educators to tour the facility, discuss SPL research activities, and explore application of these activities to their curriculum. An alternative winter snowshoe program at the top of the gondola is offered to students who do not ski, where students have a program on snow science. At the end of the day each student has a data sheet with measurements recorded from 5 locations of different elevations to take back to the classroom. Following the field trip, SPL scientists and educators visit the school for a follow-up to help children grasp concepts, represent their data set collected in graphical formats, answer questions, and evaluate students" learning. Currently, approximately 250 students annually participate in the SPL 5th and 6th grade climate education program.

Scientist in the Classroom: The First Year Highlights of a Plasma Outreach Program

NASA Astrophysics Data System (ADS)

Nagy, A.; Danielson, C. A.; Lee, R. L.; Winter, P. S.; Valentine, J. R.

1999-11-01

The General Atomics education program ``Scientist in the Classroom'' uses scientists, engineers, and technicians to discuss plasma physics with students in the classroom. A program goal is to make science an enjoyable experience while showing students how plasma physics plays an important role in their world. A fusion overview is presented, including topics on energy and environment. Using hands-on equipment, students manipulate plasma discharges using magnetic fields and observe their spectral properties. Students also observe physical properties of liquid nitrogen, infrared waves, and radioactive particles. The benefit of this program, relative to facility tours, is that it optimizes cost and scheduling between the scientific staff and students. This program and its equipment are receiving accolades as an adjunct teaching option available to schools at no cost. This year we have presented to over 1000 students at 11 schools. Student exit interviews reflect strong positive comments regarding their hands-on learning experience and science appreciation.

Fermilab Science Education Office - Classroom Presentations

Science.gov Websites

| Fermilab Home | Employees | Students | Visitors | Undergraduates Fermilab Ed Site Search Google Custom and provide your students with the opportunity to meet a Fermilab scientist or engineer. We put on engaging interactive physics presentations. These presentations will expose students to Next Generation

Promoting Pre-college Science Education

NASA Astrophysics Data System (ADS)

Taylor, P. L.; Lee, R. L.

2000-10-01

The Fusion Education Program, with continued support from DOE, has strengthened its interactions with educators in promoting pre-college science education for students. Projects aggressively pursued this year include an on-site, college credited, laboratory-based 10-day educator workshop on plasma and fusion science; completion of `Starpower', a fusion power plant simulation on interactive CD; expansion of scientist visits to classrooms; broadened participation in an internet-based science olympiad; and enhancements to the tours of the DIII-D Facility. In the workshop, twelve teachers used bench top devices to explore basic plasma physics. Also included were radiation experiments, computer aided drafting, techniques to integrate fusion science and technology in the classroom, and visits to a University Physics lab and the San Diego Supercomputer Center. Our ``Scientist in a Classroom'' program reached more than 2200 students at 20 schools. Our `Starpower' CD allows a range of interactive learning from the effects of electric and magnetic fields on charged particles to operation of a Tokamak-based power plant. Continuing tours of the DIII-D facility were attended by more than 800 students this past year.

An analysis of gender mainstreaming and education in atmospheric sciences in Ukraine

NASA Astrophysics Data System (ADS)

Godunova, V.

2009-04-01

As a participant in the international science community, Ukraine is constantly updating its understanding of worldwide trends in science and education. There is a growing demand to establish new starting points for young generations in order that they could better understand and improve our changing world. This means a renovation of school curricula. School disciplines must provide people with much more in depth information on global climate changes, their causes and effects. Scientists' involvement in the educational process could become an important factor in enhancement of educational attainments in environmental sciences. A professional scientist who is able to bring difficult research topics to the middle school students' level can be a valuable source of information. A radical political and economic transformation in the early 1990s created in Ukraine new opportunities for women and increased their interest in graduate and post-graduate studies in the sciences. The stable growth of female students has been observed. For instance, girls make up more than 70 % of university meteorology students, a percentage that is held for the last decade. In high schools and universities women make up 50 % of teachers and lectors in meteorology. Moreover, the number of female PhD scientists has been rising rather than that of male scientists. Nevertheless, the fraction of women in leading posts is considerable lower than it should be. This phenomenon is the outcome of a process that is influenced by many forces. In this paper a few suggestions and some findings from a statistics review will be presented.

Secondary School Students' Environmental Concerns and Attitudes toward Forest Ecosystem Services: Implications for Biodiversity Education

ERIC Educational Resources Information Center

Torkar, Gregor

2016-01-01

Alarming declines in biodiversity have encouraged scientists to begin promoting the idea of the services ecosystems offer to humans in order to gain support for conservation. The concept of ecosystem services is designed to communicate societal dependence on various natural ecosystems. Schools play an important role in educating students to be…

`Let your data tell a story:' climate change experts and students navigating disciplinary argumentation in the classroom

NASA Astrophysics Data System (ADS)

Walsh, Elizabeth Mary; McGowan, Veronica Cassone

2017-01-01

Science education trends promote student engagement in authentic knowledge in practice to tackle personally consequential problems. This study explored how partnering scientists and students on a social media platform supported students' development of disciplinary practice knowledge through practice-based learning with experts during two pilot enactments of a project-based curriculum focusing on the ecological impacts of climate change. Through the online platform, scientists provided feedback on students' infographics, visual argumentation artifacts that use data to communicate about climate change science. We conceptualize the infographics and professional data sets as boundary objects that supported authentic argumentation practices across classroom and professional contexts, but found that student generated data was not robust enough to cross these boundaries. Analysis of the structure and content of the scientists' feedback revealed that when critiquing argumentation, scientists initiated engagement in multiple scientific practices, supporting a holistic rather than discrete model of practice-based learning. While traditional classroom inquiry has emphasized student experimentation, we found that engagement with existing professional data sets provided students with a platform for developing expertise in systemic scientific practices during argument construction. We further found that many students increased the complexity and improved the visual presentation of their arguments after feedback.

Integrating Scientific Content with Context to Connect Educators with the Complexities and Consequences of Climate Change

NASA Astrophysics Data System (ADS)

Low, R.; Gosselin, D. C.; Oglesby, R. J.; Larson-Miller, C.; Thomas, J.; Mawalagedara, R.

2011-12-01

Over the past three years the Nebraska Earth Systems Education Network has designed professional development opportunities for K-12 and extension educators that integrates scientific content into the context of helping educators connect society with the complexities and consequences of climate change. Our professional development approach uses learner-, knowledge-, assessment-, and community-centered strategies to achieve our long-term goal: collaboration of scientists, educators and learners to foster civic literacy about climate change. Two NASA-funded projects, Global Climate Change Literacy for Educators (GCCE, 2009-2012), and the Educators Climatologists Learning Community (ECLC, 2011-2013), have provided the mechanism to provide teachers with scientifically sound and pedagogically relevant educational materials to improve climate and Earth systems literacy among educators. The primary product of the GCCE program is a 16-week, online, distance-delivered, asynchronous course entitled, Laboratory Earth: Human Dimensions of Climate Change. This course consists of four, four-week modules that integrate climate literacy, Earth Systems concepts, and pedagogy focused on active learning processes, building community, action research, and students' sense of place to promote action at the local level to address the challenges of climate change. Overall, the Community of Inquiry Survey (COI) indicated the course was effective in teaching content, developing a community of learners, and engaging students in experiences designed to develop content knowledge. A pre- and post- course Wilcoxan Signed Ranks Test indicated there was a statistically significant increase in participant's beliefs about their personal science teaching efficacy. Qualitative data from concept maps and content mastery assignments support a positive impact on teachers' content knowledge and classroom practice. Service Learning units seemed tohelp teachers connect course learning to their classroom teaching. In addition, qualitative data indicate that teachers' students found service learning to be highly motivational components to learning. The ECLC project, to be initiated in the fall 2011, will build on our GCCE experiences to create a sustainable virtual learning community of educators and scientists. Climate-change issues will serve as a context in which collaborative scientist-educator-teams will develop discrete, locally oriented research projects to facilitate development of confident, knowledgeable citizen-scientists within their classrooms.

A Dynamic Alternative to the Scientific Method

ERIC Educational Resources Information Center

Musante, Susan

2009-01-01

Scotchmoor and a team of natural scientists, social scientists, philosophers, and educators developed a Web site called Understanding Science ("www.understandingscience.org") to explain to teachers, students, and the general public "how science "really" works." The site, launched in January 2009 and funded by the National Science Foundation,…

Teaching Statistics to Social Science Students: Making It Valuable

ERIC Educational Resources Information Center

North, D.; Zewotir, T.

2006-01-01

In this age of rapid information expansion and technology, statistics is playing an ever increasing role in education, particularly also in the training of social scientists. Statistics enables the social scientist to obtain a quantitative awareness of socio-economic phenomena hence is essential in their training. Statistics, however, is becoming…

International Astronomical Search Collaboration: Online Educational Outreach Program in Astronomical Discovery for Middle School, High School, & College Students and Citizen Scientists

NASA Astrophysics Data System (ADS)

Miller, P.

2016-12-01

The International Astronomical Search Collaboration (IASC = "Isaac") in an online educational outreach program in planetary science. Citizen scientists and students from middle schools, high schools, and colleges make original discoveries of Main Belt asteroids. They discover trans-Neptunian objects and near-Earth objects. To date there have been discoveries of 1300 provisional MBAs, 7 TNOs, 2 potentially hazardous NEOs, and one Jupiter-family comet 276P/Vorobjov. IASC receives images from the Institute for Astronomy, University of Hawaii. Images are provided by the 1.8-m Pan-STARRS telescopes (PS1, PS2). These telescopes have the world's largest CCD cameras that produce 3o fields containing 1.4 billion pixels. These images are partitioned into 208 sub-images that are distributed online to the participating citizen scientists and schools (see http://iasc.hsutx.edu). Using the software Astrometrica, the sub-images are searched for moving object discoveries that are recorded with astrometry then reported to the Minor Planet Center (Smithsonian Astrophysical Observatory, Harvard). There are >5,000 citizen scientists and 700 schools that participate in the IASC asteroid searches. They come from more than 80 countries. And, the cost to participate…is free. Of the 1300 provisional MBA discoveries, 39 have been numbered and cataloged by the International Astronomical Union (Paris). The numbered discoveries are named by their citizen scientist and student discoverers. IASC works in conjunction with the NASA Asteroid Grand Challenge providing digital badging to the students (https://www.nasa.gov/feature/the-asteroid-grand-challenge-digital-badging-effort). IASC works online with the teachers from the participating schools, training them using videoconferencing to use Astrometrica in the search for, measurement of, and reporting of MBA discoveries by their students.

Developing the next generation of diverse computer scientists: the need for enhanced, intersectional computing identity theory

NASA Astrophysics Data System (ADS)

Rodriguez, Sarah L.; Lehman, Kathleen

2017-10-01

This theoretical paper explores the need for enhanced, intersectional computing identity theory for the purpose of developing a diverse group of computer scientists for the future. Greater theoretical understanding of the identity formation process specifically for computing is needed in order to understand how students come to understand themselves as computer scientists. To ensure that the next generation of computer scientists is diverse, this paper presents a case for examining identity development intersectionally, understanding the ways in which women and underrepresented students may have difficulty identifying as computer scientists and be systematically oppressed in their pursuit of computer science careers. Through a review of the available scholarship, this paper suggests that creating greater theoretical understanding of the computing identity development process will inform the way in which educational stakeholders consider computer science practices and policies.

“We Do Science Here”: Underrepresented Students’ Interactions with Faculty in Different College Contexts

PubMed Central

Hurtado, Sylvia; Eagan, M. Kevin; Tran, Minh C.; Newman, Christopher B.; Chang, Mitchell J.; Velasco, Paolo

2011-01-01

Faculty members play a key role in the identification and training of the next generation of scientific talent. In the face of the need to advance and diversify the scientific workforce, we examine whether and how specific institutional contexts shape student interactions with faculty. We conducted a mixed methods study to understand institutional contextual differences in the experiences of aspiring scientists. Data from a qualitative five-campus case study and a quantitative longitudinal study of students from over 117 higher education institutions were analyzed to determine how aspiring scientists interact with faculty and gain access to resources that will help them achieve their educational goals. Findings indicate that important structural differences exist between institutions in shaping students’ interactions with faculty. For example, students at more selective institutions typically have less frequent, less personal interactions with faculty whereas Black students at HBCUs report having more support and frequent interactions with faculty. PMID:23503924

"Let Your Data Tell a Story:" Climate Change Experts and Students Navigating Disciplinary Argumentation in the Classroom

ERIC Educational Resources Information Center

Walsh, Elizabeth Mary; McGowan, Veronica Cassone

2017-01-01

Science education trends promote student engagement in authentic knowledge in practice to tackle personally consequential problems. This study explored how partnering scientists and students on a social media platform supported students' development of disciplinary practice knowledge through practice-based learning with experts during two pilot…

Resources in Technology and Engineering: A Journey to Increase Student Engagement

ERIC Educational Resources Information Center

Akers, Ruth

2017-01-01

Increasing student achievement is a fundamental concern for many school districts and teachers. Providing students with engaging, blended STEM educational experiences may help them understand how scientists and engineers solve problems. The purpose of this article is to share teaching strategies and student activities that will not only increase…

Education News at NASA

NASA Technical Reports Server (NTRS)

2004-01-01

NASA s challenging missions provide unique opportunities for engaging and educating America s youth, the next generation of explorers. Led by Chief Education Officer Dr. Adena Williams Loston, the Agency coordinates education programs for students, faculty, and institutions in order to help inspire and motivate the scientists and engineers of the future.

Students of the World Unite

ERIC Educational Resources Information Center

Bolch, Matt

2008-01-01

This article discusses Global Learning and Observations to Benefit the Environment (GLOBE), a worldwide, hands-on science and education program for primary and secondary students. GLOBE brings together students, teachers, scientists, and community members to collaborate on inquiry-based investigations of the environment. Now in its 13th year, more…

Mentorship: The Education-Research Continuum

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

Correll, D

2008-05-29

Mentoring of science students stems naturally from the intertwined link between science education and science research. In fact, the mentoring relationship between a student and a scientist may be thought of analogically as a type of double helix forming the 'DNA' that defines the blueprint for the next generation of scientists. Although this analogy would not meet the rigorous tests commonly used for exploring the natural laws of the universe, the image depicted does capture how creating and sustaining the future science workforce benefits greatly from the continuum between education and research. The path science students pursue from their educationmore » careers to their research careers often involves training under an experienced and trusted advisor, i.e., a mentor. For many undergraduate science students, a summer research internship at a DOE National Laboratory is one of the many steps they will take in their Education-Research Continuum. Scientists who choose to be mentors share a commitment for both science education and science research. This commitment is especially evident within the research staff found throughout the Department of Energy's National Laboratories. Research-based internship opportunities within science, technology, engineering and mathematics (STEM) exist at most, if not all, of the Laboratories. Such opportunities for students are helping to create the next generation of highly trained professionals devoted to the task of keeping America at the forefront of scientific innovation. 'The Journal of Undergraduate Research' (JUR) provides undergraduate interns the opportunity to publish their scientific innovation and to share their passion for education and research with fellow students and scientists. The theme of this issue of the JUR (Vol. 8, 2008) is 'Science for All'. Almost 20 years have passed since the American Association for the Advancement of Science published its 1989 report, 'Science for All Americans-Project 2061'. The first recommendation for learning science stated: 'The Nature of Science includes the scientific world view, scientific methods of inquiry, and the nature of the scientific enterprise'. All three elements of the 'Nature of Science' are pivotal aspects of a research internship under the mentorship of an experienced and trusted advisor. In addition to internships for undergraduates, an important ingredient in realizing 'Science for All' is collaboration involving educators and scientists as they engage science students and the public at large to promote science literacy and to develop the next generation of STEM professionals. The DOE National Laboratories, individually and collectively, form an ideal nexus for nurturing these complementary collaborations. My 'Science for All' experiences at Lawrence Livermore National Laboratory (LLNL) over the last 30 years have spanned pre-college, college, and postdoctoral activities, including mentoring of undergraduate students. Early in my mentoring career, I became aware that undergraduates in particular needed help in answering the question 'what path (or paths) will lead to a challenging and rewarding STEM career'? For many, a successful path included a research internship that would result in expanded skills and training in addition to those received from their academic education. These internship skills were helpful whether the student's next Education-Research Continuum decision was graduate school or STEM employment. My experience at LLNL mirrors that of my colleagues at other DOE National Laboratories--internships with a dedicated mentor provide undergraduates with a unique set of skills that can underpin their future options and serve to improve the number, quality, and successful outcomes of students who enter STEM careers. 'Science for All' can also be found in the goals of 'The America COMPETES Act', which call for renewed efforts to increase investments in scientific research and development, strengthen education, and encourage entrepreneurship. Mentoring is an important ingredient in reaching these goals because the success of future endeavors will require a diverse workforce of scientists, technicians, engineers, mathematicians, and STEM educators. A small, but not insignificant, metric of how well the nation is doing to create the next STEM generation can be measured by the abstracts and articles published in the 'Journal of Undergraduate Research'. At the 'heart' of the JUR is the professional commitment of the DOE National Laboratory workforce to mentor the next STEM generation and to realize 'Science for All'.« less

Improving Student Writing: Methods You Can Use in Science and Engineering Classrooms

NASA Astrophysics Data System (ADS)

Hitt, S. J.; Bright, K.

2013-12-01

Many educators in the fields of science and engineering assure their students that writing is an important and necessary part of their work. According to David Lindsay, in Scientific Writing=Thinking in Words, 99% of scientists agree that writing is an integral part of their jobs. However, only 5% of those same scientists have ever had formal instruction in scientific writing, and those who are also educators may then feel unconfident in teaching this skill to their students (2). Additionally, making time for writing instruction in courses that are already full of technical content can cause it to be hastily and/or peremptorily included. These situations may be some of the contributing factors to the prevailing attitude of frustration that pervades the conversation about writing in science and engineering classrooms. This presentation provides a summary of past, present, and ongoing Writing Center research on effective writing tutoring in order to give science and engineering educators integrated approaches for working with student writers in their disciplines. From creating assignments, providing instruction, guiding revisions, facilitating peer review, and using assessments, we offer a comprehensive approach to getting your students motivated to improve their writing. Our new research study focuses on developing student writing resources and support in science and engineering institutions, with the goal of utilizing cross-disciplinary knowledge that can be used by the various constituencies responsible for improving the effectiveness of writing among student engineers and scientists. We will will draw upon recent findings in the study of the rhetoric and compositional pedagogy and apply them to the specific needs of the science and engineering classroom. The fields of communication, journalism, social sciences, rhetoric, technical writing, and philosophy of science have begun to integrate these findings into classroom practice, and we will show how these can also benefit educators in science and engineering, with the goal of producing more effective student writing.

A community of scientists: cultivating scientific identity among undergraduates within the Berkeley Compass Project

NASA Astrophysics Data System (ADS)

Aceves, Ana V.; Berkeley Compass Project

2015-01-01

The Berkeley Compass Project is a self-formed group of graduate and undergraduate students in the physical sciences at UC Berkeley. Our goals are to improve undergraduate physics education, provide opportunities for professional development, and increase retention of students from populations typically underrepresented in the physical sciences. For students who enter as freshmen, the core Compass experience consists of a summer program and several seminar courses. These programs are designed to foster a diverse, collaborative student community in which students engage in authentic research practices and regular self-reflection. Compass encourages undergraduates to develop an identity as a scientist from the beginning of their university experience.

Factors that attract veterinarians to or discourage them from research careers: a program director's perspective.

PubMed

Atchison, Michael L

2009-01-01

There is a nationwide shortage of veterinarian-scientists in the United States. Barriers to recruiting veterinary students into research careers need to be identified, and mechanisms devised to reduce these barriers. Barriers to attracting veterinary students into research careers include ignorance of available research careers and of the training opportunities. Once admitted, students in research training programs often feel isolated, fitting into neither the veterinary environment nor the research environment. To address the above issues, it is necessary to advertise and educate the public about opportunities for veterinarian-scientists. Schools need to develop high-quality training programs that are well structured but retain appropriate flexibility. Sufficient resources are needed to operate these programs so that students do not graduate with significant debt. A community of veterinarian-scientists needs to be developed so that students do not feel isolated but, rather, are part of a large community of like-minded individuals. Because of the complexities of programs that train veterinarian-scientists, it is necessary to provide extensive advising and for faculty to develop a proactive, servant-leadership attitude. Finally, students must be made aware of career options after graduation.

Changing the Face of Astronomy Through Authentic Research Experiences

NASA Astrophysics Data System (ADS)

Coble, K. A.; Bell, K'Maja; Jafri, J.; Lyon, G.; Hammergren, M.

2012-05-01

Project Exploration is a Chicago-based science outreach organization that works to ensure communities traditionally overlooked by science, particularly minority youth and girls, have access to personalized experiences with science and scientists. 85% of students participating in Project Exploration come from low-income families, primarily African-American and Latino, and 74% are girls. We particularly target students who may not be academically successful. The results of a recent 10-year retrospective study demonstrate that Project Exploration students are significantly more likely than their peers to graduate from high school (95%), go to college (50%), and major in science (60%); and they attribute their persistence in science and education to their Project Exploration experience. Furthermore, Project Exploration works with the scientists involved (including graduate students and post-docs) to help them understand what it means to do effective educational outreach and how to put the interests of the youth at the center of outreach work. In this poster, we describe the details of the Project Exploration model, as well as several projects in astronomy that our students and scientists have carried out. KB and KC are supported by NASA ROSES E/PO Grant #NNX1OAC89G. KC is also supported by the Illinois Space Grant Consortium.

Women scientists' scientific and spiritual ways of knowing

NASA Astrophysics Data System (ADS)

Buffington, Angela Cunningham

While science education aims for literacy regarding scientific knowledge and the work of scientists, the separation of scientific knowing from other knowing may misrepresent the knowing of scientists. The majority of science educators K-university are women. Many of these women are spiritual and integrate their scientific and spiritual ways of knowing. Understanding spiritual women of science would inform science education and serve to advance the scientific reason and spirituality debate. Using interviews and grounded theory, this study explores scientific and spiritual ways of knowing in six women of science who hold strong spiritual commitments and portray science to non-scientists. From various lived experiences, each woman comes to know through a Passive knowing of exposure and attendance, an Engaged knowing of choice, commitment and action, an Mindful/Inner knowing of prayer and meaning, a Relational knowing with others, and an Integrated lifeworld knowing where scientific knowing, spiritual knowing, and other ways of knowing are integrated. Consequences of separating ways of knowing are discussed, as are connections to current research, implications to science education, and ideas for future research. Understanding women scientists' scientific/ spiritual ways of knowing may aid science educators in linking academic science to the life-worlds of students.

RU COOL's scalable educational focus on immersing society in the ocean through ocean observing systems

NASA Astrophysics Data System (ADS)

Schofield, O.; McDonnell, J. D.; Kohut, J. T.; Glenn, S. M.

2016-02-01

Many regions of the ocean are exhibiting significant change, suggesting the need to develop effective focused education programs for a range of constituencies (K-12, undergraduate, and general public). We have been focused on developing a range of educational tools in a multi-pronged strategy built around using streaming data delivered through customized web services, focused undergraduate tiger teams, teacher training and video/documentary film-making. Core to the efforts is on engaging the undergraduate community by leveraging the data management tools of the U.S. Integrated Ocean Observing System (IOOS) and the education tools of the U.S. National Science Foundation's (NSF) Ocean Observing Initiative (OOI). These intuitive interactive browser-based tools reduce the barriers for student participation in sea exploration and discovery, and allowing them to become "field going" oceanographers while sitting at their desk. Those undergraduate student efforts complement efforts to improve educator and student engagement in ocean sciences through exposure to scientists and data. Through professional development and the creation of data tools, we will reduce the logistical costs of bringing ocean science to students in grades 6-16. We are providing opportunities to: 1) build capacity of scientists in communicating and engaging with diverse audiences; 2) create scalable, in-person and virtual opportunities for educators and students to engage with scientists and their research through data visualizations, data activities, educator workshops, webinars, and student research symposia. We are using a blended learning approach to promote partnerships and cross-disciplinary sharing. Finally we use data and video products to entrain public support through the development of science documentaries about the science and people who conduct it. For example Antarctic Edge is a feature length award-winning documentary about climate change that has garnered interest in movie theatres and on social media stores (NetFlix, ITunes). These combined efforts provide a range of products that all leverage off each other and provide a large suite of tools to bring the ocean to as many people as possible.

Scientist-Teacher-Student Interactions: Experiences around the Fall 2010 A-Train Symposium

NASA Astrophysics Data System (ADS)

Chambers, L. H.; Rogers, M. A.; Charlevoix, D. J.; Kennedy, T.; Oostra, D. H.

2010-12-01

In late October 2010, the second A-Train Science Symposium will be held in New Orleans, LA. (The first such event was hosted by CNES in France in 2007.) In conjunction with the symposium, a multi-faceted education event is also being planned. This will include: - Onsite one-day teacher workshops for local teachers introducing remote sensing and the use of satellite data in the classroom - Visits by scientists to local classrooms for direct interaction with students the day after the symposium - A Student-Scientist Observation Campaign which will engage A-Train scientists in a social media website with teachers and students from around the world. This paper will focus primarily on the observation campaign. It will describe the rapid development and testing of a web-based framework to support student-scientist interaction. It will lay out the steps used to activate a (hopefully significant) number of students and teachers through the GLOBE Program (www.globe.gov) and the S’COOL Project (scool.larc.nasa.gov). It will describe the interaction during the event, which will be a 3-week period before, during and after the symposium. During this time, A-Train scientists will be posting interesting satellite observations on a social media website. Students will be able to comment, ask questions, and post their own observations of related phenomena observed from the ground. Scientists will respond to student questions, and comment or ask questions on student observations. In addition, student observations will be collected through the existing S’COOL and GLOBE websites, and combined into a common visualization tool that is easily accessible through the social media framework. A photo upload pilot system is also planned, taking advantage of advances in exif photo metadata in new electronics (cell phones, smart phones, digital cameras) to easily geolocate this imagery for correlation to satellite remote sensing data and images. It is our hope that this approach will be successful and can then serve as a model for other groups to engage with students - the future scientists of the world.

Real World Connections Through Videoconferences

NASA Technical Reports Server (NTRS)

Peterson, Ruth; Lytle, John (Technical Monitor)

2002-01-01

The Learning Technologies Project (LTP) is a partner in the National Aeronautics and Space Administration's (NASA's) educational technology program unit, an electronic community center that fosters interaction, collaboration, and sharing among educators, learners, and scientists. The goal of the NASA Glenn Research Center's Learning Technologies Project is to increase students' interest and proficiency in mathematics, science, and technology through the use of computing and communications technology and by using NASA's mission in aerospace technology as a theme. The primary components are: (1) Beginner's Guide to Aeronautics, including interactive simulation packages and teacher-created online activities. (2) NASA Virtual Visits, videoconferences (with online pre-post-conference activities) connecting students and teachers to NASA scientists and researchers.

Natural Pedagogical Conversations in High School Students' Internship

ERIC Educational Resources Information Center

Hsu, Pei-Ling; Roth, Wolff-Michael; Mazumder, Asit

2009-01-01

Many science educators encourage student experiences of "authentic" science by means of student participation in science-related workplaces. Little research has been done, however, to investigate how "teaching" naturally occurs in such settings, where scientists or technicians normally do not have pedagogical training and generally do not have…

Teaching Teachers: Assessing Students as Scientists

ERIC Educational Resources Information Center

Russ, Rosemary S.; Conlin, Luke

2017-01-01

Most elementary science teachers would like to give their students opportunities to do science. The "Next Generation Science Standards" and "A Framework for K-12 Science Education" (NGSS Lead States 2013; NRC 2012) make this goal explicit by requiring that students learn how to engage in the practices of science. Consequently,…

Engaging Students with the Nature of Science and the Nature of Technology by Modeling the Work of Scientists

ERIC Educational Resources Information Center

Kruse, Jerrid W.; Wilcox, Jesse L.

2013-01-01

Just as science education is too often limited to the acquisition of facts, technology education is too often limited to proficient use of technology. Neither of these goals fully realize a robust definition of science and technology literacy. To achieve greater science and technology literacy, students must understand the natures of both science…

Student Web Use, Columbia Earthscape, and Their Implications for Online Earth Science Resources

NASA Astrophysics Data System (ADS)

Haber, J.; Luby, M.; Wittenberg, K.

2002-12-01

For three years, Columbia Earthscape, www.earthscape.org, has served as a test bed for the development and evaluation of Web-based geoscience education. Last fall (EOS Trans. AGU, 82(47), Fall Meet. Suppl., Abstract ED11A-11, 2001), we described how librarian, scientist, instructor, and student feedback led to sweeping changes in interface and acquisitions. Further assessment has looked at the value of a central online resource for Earth-system science education in light of patterns of study. Columbia Earthscape aimed to create an authoritative resource that reflects the interconnectedness of the Internet, of the disciplines of Earth-systems science, and of research, education, and public policy. Evaluation thus has three parts. The editors and editorial advisory board have evaluated projects for the site for accuracy and relevance to the project?s original context of Earth issues and topical mini-courses. Second, our research sought patterns of student use and library acquisition of Internet sources. Last, we asked if and how students benefit from Columbia Earthscape. We found, first, that while libraries are understandably reluctant to add online resources to strained budgets, almost all students work online; they vary almost solely in personal Web use. Second, Web use does not discourage use of print. Third, researchers often search Columbia Earthscape, but students, especially in schools, prefer browsing by topic of interest. Fourth, if they did not have this resource, most would surf, but many feel lost on the Web, and few say they can judge the quality of materials they used. Fifth, students found Columbia Earthscape helpful, relevant, and current, but most often for its research and policy materials. Many commented on issue-related collections original to Columbia Earthscape. While indeed we intended our Classroom Models and Sample Syllabi primarily as aids to instructor course design, we conclude, first, that students stick anyway to assigned materials and projects. Second, these assignments put students in need of materials not originally meant for education and not easy for students to evaluate. Third, an online resource must not choose simply a card-catalog or search model. In short, many have asked how scientists can support education and outreach and how curricula can integrate research and policy; but students already demand those connections, and a central online resource can help scientists, students, and the public by itself making them.

CosmoQuest: Measuring Audience Needs to Obtain Better Science

NASA Astrophysics Data System (ADS)

Buxner, Sanlyn; Bakerman, Maya; Gay, Pamela; Reiheld, Alison; CosmoQuest Team

2018-01-01

The CosmoQuest Virtual Research Facility provides a place for scientists to recruit people to aid in their science projects via citizen science. Just as students need training to be effective researchers, so do citizen scientists, but their needs are different. In this presentation, we present the results of surveys of members of the CosmoQuest community, including both citizen scientists and educators using citizen science in their classrooms. For all members of the community, we investigated the types of projects that respondents enjoyed doing, the level of difficulty they were willing to engage in, and the amount of time they spent doing citizen science projects. We also investigated what other science-related activities respondents were engaged in, other opportunities they were interested in, and what support and resources they needed to be successful in completing projects. For educators, we investigated the types of projects they wanted to engage in with their students, the ideal length of time for citizen science projects to be used in their classrooms, and the resources they needed to be able to engage students in citizen science projects effectively.

NASA Science Mission Directorate Forum Support of Scientists and Engineers to Engage in Education and Outreach

NASA Astrophysics Data System (ADS)

Buxner, S.; Grier, J.; Meinke, B. K.; Schneider, N. M.; Low, R.; Schultz, G. R.; Manning, J. G.; Fraknoi, A.; Gross, N. A.; Shipp, S. S.

2015-12-01

For the past six years, the NASA Science Education and Public Outreach (E/PO) Forums have supported the NASA Science Mission Directorate (SMD) and its E/PO community by enhancing the coherency and efficiency of SMD-funded E/PO programs. The Forums have fostered collaboration and partnerships between scientists with content expertise and educators with pedagogy expertise. As part of this work, in collaboration with the AAS Division of Planetary Sciences, we have interviewed SMD scientists, and more recently engineers, to understand their needs, barriers, attitudes, and understanding of education and outreach work. Respondents told us that they needed additional resources and professional development to support their work in education and outreach, including information about how to get started, ways to improve their communication, and strategies and activities for their teaching and outreach. In response, the Forums have developed and made available a suite of tools to support scientists and engineers in their E/PO efforts. These include "getting started" guides, "tips and tricks" for engaging in E/PO, vetted lists of classroom and outreach activities, and resources for college classrooms. NASA Wavelength (http://nasawavelength.org/), an online repository of SMD funded activities that have been reviewed by both educators and scientists for quality and accuracy, provides a searchable database of resources for teaching as well as ready-made lists by topic and education level, including lists for introductory college classrooms. Additionally, we have also supported scientists at professional conferences through organizing oral and poster sessions, networking activities, E/PO helpdesks, professional development workshops, and support for students and early careers scientists. For more information and to access resources for scientists and engineers, visit http://smdepo.org.

Student-to-Scientist (S2S) via the PACA Project: Connecting Astronomers, Educators and Students

NASA Astrophysics Data System (ADS)

Yanamandra-Fisher, P. A.

2015-12-01

Student to Scientist (S2S), provides pathways for observational and research tools for K-12 and undergraduate students to improve science proficiency through conducting real scientific observations. Our approach lies in the integration of professional and amateur astronomers, educators, students, and communicators to identify multiple paths for the student to become a scientist. I report on the ensuing project, also known as the PACA Project, which is an ecosystem of various activities that take advantage of the social media and immediate connectivity amongst amateur astronomers worldwide and that can be galvanized to participate in a given observing campaign. The PACA Project has participated in organized campaigns such as NASA Comet ISON Observing Campaign in 2013; NASA Comet Integrated Observations Campaign to observe Comet Siding Spring as it flew by very close to Mars on 19 October 2014. Currently the PACA Project is involved in the Ground-based Amateur campaign to observer ESA/Rosetta mission's target, 67P/Churyumov-Gerasimenko (CG) that is en route to its perihelion on 13 August 2015 (at the time of abstract submission). The PACA Project provides access to the professional community and the student/educator and informal/public communities via various social media like Facebook, Twitter, Flickr, Pinterest, Vimeo, Google+. With the popularity of mobile platforms and instant connections with other peers globally, the multi-faceted social universe has become a vital part of engagement of multiple communities. The PACA project currently has initiated a Comet Tails and Disconnection Events campaign to relate to the changing solar wind conditions. Other PACA projects include Saturn Solstice 2017 and outreach projects with Astroproject (India). These and other citizen-science enabled activities and their integration with S2S project will be discussed.

Sharing Planetary Science on a Regional Scale

NASA Astrophysics Data System (ADS)

Runyon, C. R.; Colgan, M.

2001-12-01

Fifteen southeastern Space Grant Consortia (AL, AK, DL, DC, FL, GA, KY, LA, MD, Mississippi, NC, PR, SC, TN, VI, VA) have joined together to form the Office of Space Science (OSS) Southeastern Regional Clearing House, or SERCH. The objectives of SERCH are to produce a network of science educators and OSS scientists, to assess the region's educational needs and strengths, and to tailor OSS education material and data to the need of the southeastern educators and students. SERCH serves as a facilitator and broker of services by a two-way interface between the southeastern region's diverse educational community and national scientists and engineers involved in OSS's flight missions and research programs. Our goal is to make SERCH a "one-stop educational service center" for the science, mathematics and technology educators needing OSS material and OSS scientists needing help in developing educational material. We promote the development of partnerships among educators and scientists to accomplish the educational and outreach missions of the OSS. These partnerships create and sustain educational programs that are effective, locally useful, yet national in scope. Our strategies include respecting the diversity of our audiences, listening to their needs and working closely with both the product developers and end-users to ensure that the materials and resources are effective, scientifically correct and fun to use.

International Collaborations in Large Geophysical Experiments: A Win-Win Situation

NASA Astrophysics Data System (ADS)

Keller, G. R.

2007-12-01

It has been my privilege to be involved in a significant number of large international cooperative geophysical experiments. These logistically challenging efforts all took place in developing or under-developed countries and were co-driven at least to some extent by scientists in the host country. A team of scientists from developed countries were involved in each case but were not always the leaders of the effort. The host countries were all supportive and played roles ranging from simply facilitating the effort to providing most of the funding. Some lessons learned from these efforts were the following: 1) permissions for large efforts must come from very high levels in the host government; 2) the host scientists should never be overlooked or underestimated; 3) involving students from both the host country and developed countries produces big educational and cultural dividends for all involved (it is a life experience for the visitors and a chance to widen perspectives and even acquire advanced degrees for the students from the host countries); 4) providing funds for scientists and students from the host country to visit their international partners to participate in the data processing and analysis and to attend scientific meetings is extremely important; 5) return trips to the host country to collaborate on data processing and analysis and to consolidate partnerships are also important; 6) the partnership with the host country should be viewed as a long term commitment to scientific cooperation and education that benefits all involved. Our experiences have encountered only a few roadblocks and have been ultimately universally positive. Lifelong relationships have been forged, students have been educated and enriched, and excellent scientific results have been produced.

The Teacher/Scientist: From Trainer to Educator.

ERIC Educational Resources Information Center

Ellerbrock, Michael J.

Problems and issues in U.S. undergraduate education are identified, and 10 recommendations for improvement are offered. Specific reference is made to agriculture faculty. Problems and issues include: current emphasis on academic specialization rather than the development of integrated, holistic students; the purpose of a liberal education versus…

Pride and Peril: Historically Black Colleges and Universities

ERIC Educational Resources Information Center

Nealy, Michelle J.

2009-01-01

Once a beacon of hope for thousands of Black students denied access to higher education by predominantly White institutions, historically Black colleges and universities (HBCUs) have educated generations of Black scientists, doctors, lawyers, educators and social activists. But today, these institutions face serious challenges. Questions of…

Teaching Experiences for Graduate Student Researchers: A Study of the Design and Implementation of Science Courses for Secondary Students

NASA Astrophysics Data System (ADS)

Collins, Anne Wrigley

Modern science education reform recommends that teachers provide K-12 science students a more complete picture of the scientific enterprise, one that lies beyond content knowledge and centers more on the processes and culture of scientists. In the case of Research Experience for Teachers (RET) programs, the "teacher" becomes "researcher" and it is expected that he/she will draw from the short-term science research experience in his/her classroom, offering students more opportunities to practice science as scientists do. In contrast, this study takes place in a program that allows graduate students, engaged in research full-time, to design and implement a short-duration course for high school students on Saturdays; the "researcher" becomes "teacher" in an informal science program. In this study, I investigated eleven graduate students who taught in the Saturday Science (SS) program. Analyses revealed participants' sophisticated views of the nature of science. Furthermore, participants' ideas about science clearly resonated with the tenets of NOS recommended for K-12 education (McComas et al., 1998). This study also highlighted key factors graduate students considered when designing lessons. Instructors took great care to move away from models of traditional, "lecture"-based, university science teaching. Nonetheless, instruction lacked opportunities for students to engage in scientific inquiry. In instances when instructors included discussions of NOS in SS courses, opportunities for high school students to learn NOS were not explicit enough to align with current science reform recommendations (e.g., AAAS, 2009). Graduate students did, however, offer high school students access to their own science or engineering research communities. These findings have significant implications for K-12 classroom reform. Universities continue to be a valuable resource for K-12 given access to scientists, materials or equipment, and funding. Nonetheless, and as was the case with graduate students in this study, scientists who engage in partnerships with K-12 need explicit training on effective science teaching methodologies just as classroom teachers need this training. In other words, despite membership in the science research community -- thus sound understanding of authentic science practice -- university scientists may not be prepared to or understand the importance of translating this for K-12 partners.

A Solid Earth educational module, co-operatively developed by scientists and high school teachers through the Scripps Classroom Connection GK12 Program

NASA Astrophysics Data System (ADS)

Ziegler, L. B.; van Dusen, D.; Benedict, R.; Chojnacki, P. R.; Peach, C. L.; Staudigel, H.; Constable, C.; Laske, G.

2010-12-01

The Scripps Classroom Connection, funded through the NSF GK-12 program, pairs local high school teachers with Scripps Institution of Oceanography (SIO) graduate students in the earth and ocean sciences for their mutual professional development. An integral goal of the program is the collaborative production of quality earth science educational modules that are tested in the classroom and subsequently made freely available online for use by other educators. We present a brief overview of the program structure in place to support this goal and illustrate a module that we have developed on the Solid Earth & Plate Tectonics for a 9th grade Earth Science classroom. The unit includes 1) an exercise in constructing a geomagnetic polarity timescale which exposes students to authentic scientific data; 2) activities, labs, lectures and worksheets that support the scientific content; and 3) use of online resources such as Google Earth and interactive animations that help students better understand the concepts. The educational unit is being implemented in two separate local area high schools for Fall 2010 and we will report on our experiences. The co-operative efforts of teachers and scientists lead to educational materials which expose students to the scientific process and current science research, while teaching basic concepts using an engaging inquiry-based approach. In turn, graduate students involved gain experience communicating their science to non-science audiences.

Telepresence and real-time data transmission from Axial Seamount: implications for education and community engagement utilizing the OOI-RSN cabled observatory

NASA Astrophysics Data System (ADS)

Fundis, A. T.; Kelley, D. S.; Sautter, L. R.; Proskurowski, G.; Kawka, O.; Delaney, J. R.

2011-12-01

Axial Seamount, the most robust volcanic system on the Juan de Fuca Ridge, is a future site of the cabled observatory component of the National Science Foundation's Ocean Observatories Initiative (OOI) (see Delaney et al; Proskurowski et al., this meeting). In 2014, high-bandwidth data, high-definition video and digital still imagery will be streamed live from the cable observatory at Axial Seamount via the Internet to researchers, educators, and the public. The real-time data and high-speed communications stream will open new approaches for the onshore public and scientists to experience and engage in sea-going research as it is happening. For the next 7 years, the University of Washington and the OOI will collaboratively support an annual multi-week cruise aboard the research vessel Thomas G. Thompson. These "VISIONS" cruises will include scientific and maintenance operations related to the cabled network, the OOI Regional Scale Nodes (RSN). Leading up to 2014, VISIONS cruises will also be used to engage students, educators, scientists and the public in science focused at Axial Seamount through avenues that will be adaptable for the live data stream via the OOI-RSN cable. Here we describe the education and outreach efforts employed during the VISIONS'11 cruise to Axial Seamount including: 1) a live HD video stream from the seafloor and the ship to onshore scientists, educators, and the public; 2) a pilot program to teach undergraduates from the ship via live and taped broadcasts; 3) utilizing social media from the ship to communicate with scientists, educators, and the public onshore; and 4) providing undergraduate and graduate students onboard immersion into sea-going research. The 2011 eruption at Axial Seamount (see Chadwick et al., this meeting) is a prime example of the potential behind having these effective tools in place to engage the scientific community, students, and the public when the OOI cabled observatory comes online in 2014.

Northwest Tribal Interaction with Washington State University: Research and Education Opportunities Afforded Through the Center for Multiphase Environmental Research

NASA Astrophysics Data System (ADS)

Rumburg, B.; Yonge, D.; Jacob, J.

2003-12-01

The under-representation of Native Americans in engineering and science at the student and practicing engineer or scientist level is a national problem. To begin addressing this problem Washington State University (WSU) has initiated discussio with local Native American tribes to strengthen the relationship between WSU and the tribes and to improve the educational opportunities available to tribal members. The Center for Multiphase Environmental Research (CMER) received a 1999 National Science Foundation (NSF) Integrative Graduate Education and Research Training (IGERT) grant to train Ph.D. students. The main goal of the program is to foster multidisciplinary research and education for future scientists and engineers in the broad field of study that incorporates the fate and transport of environmentally significant species between interfaces. We are also focused on recruiting and educating Native American students. CMER is committed to cultivating its relationship with Native American tribes by identifying the environmental concerns of the tribes and developing collaborative research efforts utilizing CMER's infrastructure. Through these collaborative projects the CMER hopes to better understand the social and cultural aspects important to the tribes and develop the familiarity needed to effectively enhance student recruitment. This poster highlights the CMER's interdisciplinary research and teaching efforts and focuses on Native American recruitment.

The cultural production of "science" and "scientist" in high school physics: Girls' access, participation, and resistance

NASA Astrophysics Data System (ADS)

Carlone, Heidi Berenson

2000-10-01

For over three decades, the gender gap in science and science education has received attention from teachers, policy makers, and scholars of various disciplines. During this time, feminist scholars have posited many reasons why the gender gap in science and science education exists. Early feminist discourse focused on girls' "deficits," while more recent work has begun to consider the problems with science and school science in the quest for a more gender inclusive science. Specifically, feminist scholars advocate a transformation of both how students learn science and the science curriculum that students are expected to learn. This study was designed to examine more deeply this call for a changed science curriculum and its implications for girls' participation, interest, and scientist identities. If we reinvisioned ways to "do" science, "learn" science, and "be a scientist" in school science, would girls come to see science as something interesting and worth pursuing further? This question framed my ethnographic investigation. I examined the culturally produced meanings of "science" and "scientist" in two high school physics classrooms (one traditional and one non-traditional class framed around real-world themes), how these meanings reproduced and contested larger sociohistorical (and prototypical) meanings of science and scientist, and how girls participated within and against these meanings. The results complicate the assumption that a classroom that enacts a non-traditional curriculum is "better" for girls. This study explained how each classroom challenged sociohistorical legacies of school science in various "spaces of possibility" and how prototypical meanings pushed the potential of these spaces to the margins. Girls in the traditional physics class generally embraced prototypical meanings because they could easily access "good student" identities. Girls in the non-traditional class, though attracted to alternative practices, struggled with the conflicting promoted student identities that did not allow them easy access to "good student" identities. In neither class were girls' perceptions of what it meant to do science and be a scientist challenged. And, in neither class did girls connect to a legitimate scientist identity. These findings leave unanswered the question of whether changes in pedagogy and curriculum alone will produce more gender fair school science.

No Duck Left behind

ERIC Educational Resources Information Center

Cooper, Sandi; Thomas, Julie; Motley, Tammy

2011-01-01

Recently, a group of fourth graders joined "Pintail Partners"--a year-long collaborative research effort of scientists, students, classroom teachers, preservice teachers, museum educators, and university professors. Students and teachers followed satellite tracking data (marking the pintail duck's spring migration) and interacted with scientists…

Qualitative Research Methods in Education and Educational Technology. Research Methods for Educational Technology

ERIC Educational Resources Information Center

Willis, Jerry W.

2008-01-01

"Qualitative Research Methods in Education and Educational Technology" was written for students and scholars interested in exploring the many qualitative methods developed over the last 50 years in the social sciences. The book does not stop, however, at the boundaries of the social sciences. Social scientists now consume and use research methods…

Incorporating Genomics and Bioinformatics across the Life Sciences Curriculum

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

Ditty, Jayna L.; Kvaal, Christopher A.; Goodner, Brad

Undergraduate life sciences education needs an overhaul, as clearly described in the National Research Council of the National Academies publication BIO 2010: Transforming Undergraduate Education for Future Research Biologists. Among BIO 2010's top recommendations is the need to involve students in working with real data and tools that reflect the nature of life sciences research in the 21st century. Education research studies support the importance of utilizing primary literature, designing and implementing experiments, and analyzing results in the context of a bona fide scientific question in cultivating the analytical skills necessary to become a scientist. Incorporating these basic scientific methodologiesmore » in undergraduate education leads to increased undergraduate and post-graduate retention in the sciences. Toward this end, many undergraduate teaching organizations offer training and suggestions for faculty to update and improve their teaching approaches to help students learn as scientists, through design and discovery (e.g., Council of Undergraduate Research [www.cur.org] and Project Kaleidoscope [www.pkal.org]). With the advent of genome sequencing and bioinformatics, many scientists now formulate biological questions and interpret research results in the context of genomic information. Just as the use of bioinformatic tools and databases changed the way scientists investigate problems, it must change how scientists teach to create new opportunities for students to gain experiences reflecting the influence of genomics, proteomics, and bioinformatics on modern life sciences research. Educators have responded by incorporating bioinformatics into diverse life science curricula. While these published exercises in, and guidelines for, bioinformatics curricula are helpful and inspirational, faculty new to the area of bioinformatics inevitably need training in the theoretical underpinnings of the algorithms. Moreover, effectively integrating bioinformatics into courses or independent research projects requires infrastructure for organizing and assessing student work. Here, we present a new platform for faculty to keep current with the rapidly changing field of bioinformatics, the Integrated Microbial Genomes Annotation Collaboration Toolkit (IMG-ACT). It was developed by instructors from both research-intensive and predominately undergraduate institutions in collaboration with the Department of Energy-Joint Genome Institute (DOE-JGI) as a means to innovate and update undergraduate education and faculty development. The IMG-ACT program provides a cadre of tools, including access to a clearinghouse of genome sequences, bioinformatics databases, data storage, instructor course management, and student notebooks for organizing the results of their bioinformatic investigations. In the process, IMG-ACT makes it feasible to provide undergraduate research opportunities to a greater number and diversity of students, in contrast to the traditional mentor-to-student apprenticeship model for undergraduate research, which can be too expensive and time-consuming to provide for every undergraduate. The IMG-ACT serves as the hub for the network of faculty and students that use the system for microbial genome analysis. Open access of the IMG-ACT infrastructure to participating schools ensures that all types of higher education institutions can utilize it. With the infrastructure in place, faculty can focus their efforts on the pedagogy of bioinformatics, involvement of students in research, and use of this tool for their own research agenda. What the original faculty members of the IMG-ACT development team present here is an overview of how the IMG-ACT program has affected our development in terms of teaching and research with the hopes that it will inspire more faculty to get involved.« less

Teachers engaging in Authentic Education Research as They Engage Students in Authentic Science Research: A Collaboration Among Scientists, Education Researchers and Practitioners

NASA Astrophysics Data System (ADS)

Schielack, J. F.; Herbert, B. E.

2004-12-01

The ITS Center for Teaching and Learning (http://its.tamu.edu) is a five-year NSF-funded collaborative effort to engage scientists, educational researchers, and educators in the use of information technology to enhance science teaching and learning at Grades 7 - 16. The ITS program combines graduate courses in science and science education leadership for both science and education graduate students with professional development experiences for classroom teachers. The design of the ITS professional development experience is based upon the assumption that science and mathematics teaching and learning will be improved when they become more connected to the authentic science research done in field settings or laboratories. The effective use of information technology to support inquiry in science classrooms has been shown to help achieve this objective. In particular, the professional development for teachers centers around support for implementing educational research in their own classrooms on the impacts of using information technology to promote authentic science experiences for their students. As a design study that is "working toward a greater understanding of the "learning ecology," the research related to the creation and refinement of the ITS Center's collaborative environment for integrating professional development for faculty, graduate students, and classroom teachers is contributing information about an important setting not often included in the descriptions of professional development, a setting that incorporates distributed expertise and resulting distributed growth in the various categories of participants: scientists, science graduate students, education researchers, science education graduate students, and master teachers. Design-based research is an emerging paradigm for the study of learning in context through the systematic design and study of instructional strategies and tools. In this presentation, we will discuss the results of the formative evaluation process that has moved the ITS Center's collaborative environment for professional development through the iterative process from Phase I (the planned program designed in-house) to Phase II (the experimental program being tested in-house). Phase II highlighted learning experiences over two summers focused on the exploration of environmentally-related science, technology, engineering or mathematics (STEM) topics through the use of modeling, visualization and complex data sets to explore authentic scientific questions that can be integrated within the 7-16 curriculum.

Clinician scientist training program: a proposal for training medical students in clinical research.

PubMed

Mark, A L; Kelch, R P

2001-11-01

There is national alarm about a decline in the number of clinician scientists. Most of the proposed solutions have focused on housestaff and junior faculty. We propose a new national program for training medical students in clinical research. This program, coined "Clinician Scientist Training Program" (CSTP), would consist of a combined degree program in medicine (MD) and clinical research (eg, masters in translational research or masters in clinical epidemiology). Students could enroll in the program at any stage during medical school. After 3 years of medical school, students would spend at least 2 years in a combined didactic and mentored clinical research training program and then complete medical school. Students could elect to pursue more prolonged clinical research training toward a combined PhD and MD. The CSTP is designed to meet six critical challenges: 1) engage students early in clinical research training; 2) provide a didactic clinical research curriculum; 3) expose students to several years of mentored clinical research training; 4) promote debt prevention by providing tuition payments during medical education and a stipend during clinical research training; 5) facilitate prolonged exposure to a community of peers and mentors in a program with national and institutional identity and respect; and 6) permit enrollment in the program as students enter medical school or at any stage during medical school. If the success of the Medical Scientist Training Program in training medical students in basic research is a guide, the CSTP could become a linchpin for training future generations of clinician scientists.

Scientists and Science Education: Working at the Interface

NASA Astrophysics Data System (ADS)

DeVore, E. K.

2004-05-01

"Are we alone?" "Where did we come from?" "What is our future?" These questions lie at the juncture of astronomy and biology: astrobiology. It is intrinsically interdisciplinary in its study of the origin, evolution and future of life on Earth and beyond. The fundamental concepts of origin and evolution--of both living and non-living systems--are central to astrobiology, and provide powerful themes for unifying science teaching, learning, and appreciation in classrooms and laboratories, museums and science centers, and homes. Research scientists play a key role in communicating the nature of science and joy of scientific discovery with the public. Communicating the scientific discoveries with the public brings together diverse professionals: research scientists, graduate and undergraduate faculty, educators, journalists, media producers, web designers, publishers and others. Working with these science communicators, research scientists share their discoveries through teaching, popular articles, lectures, broadcast and print media, electronic publication, and developing materials for formal and informal education such as textbooks, museum exhibits and documentary television. There's lots of activity in science communication. Yet, the NSF and NASA have both identified science education as needing improvement. The quality of schools and the preparation of teachers receive national attention via "No Child Left Behind" requirements. The number of students headed toward careers in science, technology, engineering and mathematics (STEM) is not sufficient to meet national needs. How can the research community make a difference? What role can research scientists fulfill in improving STEM education? This talk will discuss the interface between research scientists and science educators to explore effective roles for scientists in science education partnerships. Astronomy and astrobiology education and outreach projects, materials, and programs will provide the context for this discussion.

JR Live: Lessons Learned from Ship-to-Shore Interactions with the JOIDES Resolution

NASA Astrophysics Data System (ADS)

Cooper, S. K.

2016-02-01

Live ship-to-shore events have been conducted regularly from the International Ocean Discovery Program (IODP) research vessel JOIDES Resolution since 2009. These 45-minute events have reached thousands of students, educators and members of the general public with the JR's cutting edge science and technology and the excitement of discovery, science process and careers. Conducted by trained on-board Education/Outreach Officers on board the JR's two-month expeditions, the programs vary over time and have evolved with available technology. Each event incorporates collaboration between the Education Officer, scientists who are a part of the expedition science party, and requests from shore-side audiences. These collaborations have been successful in igniting interest among students and educators, providing scientists with outreach experiences and in meeting education standards and goals. Over the past six years, many lessons have been learned about procedures, technology, content, follow-up and impact. This session will share some of these lessons, identify opportunities for collaboration and engagement, and explore growth opportunities and directions.

Education and Outreach from the JOIDES Resolution during IODP Expedition 360 : linking onboard research and classroom activities during and after the Expedition.

NASA Astrophysics Data System (ADS)

Burgio, M.; Zhang, J.; Kavanagh, L.; Martinez, A. O.; Expedition 360 Scientists, I.

2016-12-01

The International Ocean Discovery Program (IODP) expeditions provide an excellent opportunity for onboard Education Officers (EO) to communicate and disseminate exciting shipboard research and discoveries to students around the world. During expedition 360, the EOs carried out 140 live webcasts, using different strategies to create an effective link between both students and scientists. Below are examples of strategies we used: -Primary school: The Beauty of Gabbro! and Life in the rocks! During the webcasts, students could virtually tour the ship, interview scientists, and see and discuss samples of the cored gabbro and minerals in thin sections. Artistic contextualization by J. Zhang, facilitated these activities. Moreover, highlighting the search for microbes in the Earth's crust , was particularly successful in engaging the students. -Middle and High school: Fun and relationships in science. Students were able to email expert scientists in the scientific discipline they chose to research and interview them during a live webcast. Some students created a song about the expedition. "on the boat - cup song - IODP project" https://www.youtube.com/watch?v=qex-w9aSV7c-University: Travels, research and the everyday life of professors onboard. We used webcasts to connect with universities in France, Japan and Italy, to create vibrant interactions between students and scientists that enabled students to get closer to their professors and understand better the life of onboard researchers. In collaboration with the science party we developed new strategies to keep in touch with students after completion of the cruise. We generated teaching kits consisting of pedaqgoical sets of pictures, exercises using onboard data, a continuously updated map "tracking geologists", and live webcasts to be organized from laboratories to schools. We already have had enthusiastic feedback from teachers that took part in our webcasts and the challenge is to continue to foster the relationships we created.

Explorers of the Universe: Interactive Collaborations via the Internet

NASA Astrophysics Data System (ADS)

Burks, G.

1999-05-01

This proposal details how self-directed case-based research with earth/space investigations, and instruction together with collaborative interactions with teachers, students, scientists, and university educators using metacognitive tools (e.g., concept maps, interactive vee diagrams, and thematic organizers), and innovative technology promotes meaningful learning in ways that differ from conventional and atypical educational settings. Our Explorers of the Universe Scientific/Literacy project (http://explorers.tsuniv.edu) promotes earth/space science inquires in non-conventional learning environments with middle, secondary, and postsecondary students. Outlined are programs and educational processes and outcomes that meet both local and national contexts for achieving meaningful learner-centered science and mathematics goals. All information is entered electronically by students and collected for analyses in a database at our TSU web server. Scientists and university educators review and respond to these postings of students by writing in their electronic notebooks, commenting on their concept maps and interactive vee diagrams, and guiding them to pertinent papers and journal articles. Teachers are active learners with their students. They facilitate the learning process by guiding students in their inquires, evoking discussions, and involving their students with other affiliated schools whose students may be engaged in similar research topics. Teachers manage their student electronic accounts by assigning passwords, determining the degree of portfolio sharing among students, and responding to student inquires. Students post their thoughts, progress, inquires, and data on their individualized electronic notebook. Likewise, they plan, carry out, and finalize their case-based research using electronic transmissions via e-mail and the Internet of their concept maps and interactive vee diagrams. Their peer-edited papers are posted on the WWW for others to read and react. The final process involves students developing CDs of their case research report, which serves as a longitudinal case for others to pursue.

A Guide for Scientists Interested in Researching Student Outcomes

NASA Astrophysics Data System (ADS)

Buxner, Sanlyn R.; Anbar, Ariel; Semken, Steve; Mead, Chris; Horodyskyj, Lev; Perera, Viranga; Bruce, Geoffrey; Schönstein, David

2015-11-01

Scientists spend years training in their scientific discipline and are well versed the literature, methods, and innovations in their own field. Many scientists also take on teaching responsibilities with little formal training in how to implement their courses or assess their students. There is a growing body of literature of what students know in space science courses and the types of innovations that can work to increase student learning but scientists rarely have exposure to this body of literature. For scientists who are interested in more effectively understanding what their students know or investigating the impact their courses have on students, there is little guidance. Undertaking a more formal study of students poses more complexities including finding robust instruments and employing appropriate data analysis. Additionally, formal research with students involves issues of privacy and human subjects concerns, both regulated by federal laws.This poster details the important decisions and issues to consider for both course evaluation and more formal research using a course developed, facilitated, evaluated and researched by a hybrid team of scientists and science education researchers. HabWorlds, designed and implemented by a team of scientists and faculty at Arizona State University, has been using student data to continually improve the course as well as conduct formal research on students’ knowledge and attitudes in science. This ongoing project has had external funding sources to allow robust assessment not available to most instructors. This is a case study for discussing issues that are applicable to designing and assessing all science courses. Over the course of several years, instructors have refined course outcomes and learning objectives that are shared with students as a roadmap of instruction. The team has searched for appropriate tools for assessing student learning and attitudes, tested them and decided which have worked, or not, for assessment in the course. Data from this assessment has led to many changes in the course to better meet the course goals. We will share challenges and lessons learned in our project to assist other instructors interested in doing research on student outcomes.

Student and Community Engagement in Earth, Space, and Environmental Sciences Through Experiential Learning and Citizen Science as Part of Research Broader Impact

NASA Astrophysics Data System (ADS)

Ibrahim, Alaa; Ahmed, Yasmin

2015-04-01

Fulfilling the broader impact of a research project in Earth and environmental sciences is an excellent opportunity for educational and outreach activities that connect scientists and society and enhance students and community engagement in STEM fields in general and in Earth, space, and environmental sciences in particular. Here we present the experience developed in this endeavor as part of our Partnerships for Enhanced Engagement in Research (PEER) project sponsored by USAID/NSF/NAS. The project introduced educational and outreach activities that included core curriculum course development for university students from all majors, community-based learning projects, citizen science and outreach programs to school students and community members. Through these activities, students worked with the project scientists on a variety of activities that ranged from citizen science and undergraduate research to run mass experiments that measure the quality of air, drinking water, and ultraviolet level in greater Cairo, Egypt, to community awareness campaigns through the production of short documentaries and communicating them with stakeholders and target groups, including schools and TV stations. The activities enhanced students learning and the public awareness on climate change and the underlying role of human activities. It also connected effectively the project scientists with college and university students a well as the wider segments of the society, which resulted in a host of benefits including better scientific literacy and appreciation to the role of scientists, promoting scientists as role models, sharing the values of science, and motivating future generations to puruse a career in science This work is part of the PEER research project 2-239 sponsored by USAID/NSF/NAS Project Link (at National Academies website): http://sites.nationalacademies.org/PGA/dsc/peerscience/PGA_084046.htm website: http://CleanAirEgypt.org Links to cited work: Core Curriculum Course: http://bit.ly/FutureLife Citizen Science Project: Quality of Air, Drinking Water, and U.V. Level in Greater Cairo: Map 1: http://bit.ly/AirWaterLightMap1 Map 2: http://bit.ly/AirWaterLightMap2 Short Documentaries Student Projects: https://vimeo.com/science2society/videos Project video: https://vimeo.com/100427525

Student and Community Engagement in Earth, Space, and Environmental Sciences Through Experiential Learning and Citizen Science as Part of Research Broader Impact

NASA Astrophysics Data System (ADS)

Ibrahim, A. I.; Tutwiler, R.; Zakey, A.; Shokr, M. E.; Ahmed, Y.; Jereidini, D.; Eid, M.

2014-12-01

Fulfilling the broader impact of a research project in Earth and environmental sciences is an excellent opportunity for educational and outreach activities that connect scientists and society and enhance students and community engagement in STEM fields in general and in Earth, space, and environmental sciences in particular. Here we present the experience developed in this endeavor as part of our Partnerships for Enhanced Engagement in Research (PEER) project sponsored by USAID/NSF/NAS. The project introduced educational and outreach activities that included core curriculum course development for university students from all majors, community-based learning projects, citizen science and outreach programs to school students and community members. Through these activities, students worked with the project scientists on a variety of activities that ranged from citizen science and undergraduate research to run mass experiments that measure the quality of air, drinking water, and ultraviolet level in greater Cairo, Egypt, to community awareness campaigns through the production of short documentaries and communicating them with stakeholders and target groups, including schools and TV stations. The activities enhanced students learning and the public awareness on climate change and the underlying role of human activities. It also connected effectively the project scientists with college and university students a well as the wider segments of the society, which resulted in a host of benefits including better scientific literacy and appreciation to the role of scientists, promoting scientists as role models, sharing the values of science, and motivating future generations to puruse a career in science Note: This presentation is a PEER project sponsored by USAID/NSF/NAS Project Link (at National Academies website): http://sites.nationalacademies.org/PGA/dsc/peerscience/PGA_084046.htmwebsite: http://CleanAirEgypt.orgLinks to cited work: Core Curriculum Course: http://bit.ly/FutureLife Citizen Science Project: Quality of Air, Drinking Water, and U.V. Level in Greater Cairo: Map 1: http://bit.ly/AirWaterLightMap1 Map 2: http://bit.ly/AirWaterLightMap2 Short Documentaries Student Projects: https://vimeo.com/science2society/videos Project video: http://CleanAirEgypt.org

How Do Scientists Decide Which is the Better Theory? Crustal Evaluation Education Project. Teacher's Guide [and] Student Investigation.

ERIC Educational Resources Information Center

Stoever, Edward C., Jr.

Crustal Evolution Education Project (CEEP) modules were designed to: (1) provide students with the methods and results of continuing investigations into the composition, history, and processes of the earth's crust and the application of this knowledge to man's activities and (2) to be used by teachers with little or no previous background in the…

Making Sense of Scientific Biographies: Scientific Achievement, Nature of Science, and Storylines in College Students' Essays

ERIC Educational Resources Information Center

Hwang, Seyoung

2015-01-01

In this article, the educative value of scientific biographies will be explored, especially for non-science major college students. During the "Scientist's life and thought" course, 66 college students read nine scientific biographies including five biologists, covering the canonical scientific achievements in Western scientific history.…

Scientists: Get Involved in Planetary Science Education and Public Outreach! Here’s How!

NASA Astrophysics Data System (ADS)

Buxner, Sanlyn; Dalton, H.; Shipp, S.; CoBabe-Ammann, E.; Scalice, D.; Bleacher, L.; Wessen, A.

2013-10-01

The Planetary Science Education and Public Outreach (E/PO) Forum is a team of educators, scientists, and outreach professionals funded by NASA’s Science Mission Directorate (SMD) that supports SMD scientists currently involved in E/PO - or interested in becoming involved in E/PO efforts - to find ways to do so through a variety of avenues. There are many current and future opportunities and resources for scientists to become engaged in E/PO. The Forum provides tools for responding to NASA SMD E/PO funding opportunities (webinars and online proposal guides), a one-page Tips and Tricks guide for scientists to engage in education and public outreach, and a sampler of activities organized by thematic topic and NASA’s Big Questions in planetary science. Scientists can also locate resources for interacting with diverse audiences through a number of online clearinghouses, including: NASA Wavelength, a digital collection of peer-reviewed Earth and space science resources for educators of all levels (http://nasawavelength.org); the Year of the Solar System website (http://solarsystem.nasa.gov/yss), a presentation of thematic resources that includes background information, missions, the latest in planetary science news, and educational products, for use in the classroom and out, for teaching about the solar system organized by topic - volcanism, ice, astrobiology, etc.; and EarthSpace (http://www.lpi.usra.edu/earthspace), a community website where faculty can find and share resources and information about teaching Earth and space sciences in the undergraduate classroom, including class materials, news, funding opportunities, and the latest education research. Also recently developed, the NASA SMD Scientist Speaker’s Bureau (http://www.lpi.usra.edu/education/speaker) offers an online portal to connect scientists interested in getting involved in E/PO projects - giving public talks, classroom visits, and virtual connections - with audiences. Learn more about the opportunities to become involved in E/PO and to share your science with students, educators, and the general public at http://smdepo.org.

Math and Science. IDRA Focus.

ERIC Educational Resources Information Center

IDRA Newsletter, 1995

1995-01-01

This theme issue contains six articles on improving math and science education for minority group students, particularly language-minority students. "Accelerating Content Area Gains for English Language Learners" (Laura Chris Green) describes the Young Scientists Acquiring English project, which seeks to improve the content-area…

Know Where Lead May Be Hiding

MedlinePlus

... might like ... Sing-Along Songs With words and music! Go! What's That Word Scientific Dictionary Not sure of what a word means? Find Out! For teachers The Environmental Health Science Education website provides educators, students and scientists with easy access to reliable tools, ...

AGU Pathfinder: Career and Professional Development Resources for Earth and Space Scientists

NASA Astrophysics Data System (ADS)

Harwell, D. E.; Asher, P. M.; Hankin, E. R.; Janick, N. G.; Marasco, L.

2017-12-01

The American Geophysical Union (AGU) is committed to inspiring and educating present and future generations of diverse, innovative, and creative Earth and space scientists. To meet our commitment, AGU provides career and educational resources, webinars, mentoring, and support for students and professionals at each level of development to reduce barriers to achievement and to promote professional advancement. AGU is also working with other organizations and educational institutions to collaborate on projects benefiting the greater geoscience community. The presentation will include an overview of current Pathfinder efforts, collaborative efforts, and an appeal for additional partnerships.

Preparing Planetary Scientists to Engage Audiences

NASA Astrophysics Data System (ADS)

Shupla, C. B.; Shaner, A. J.; Hackler, A. S.

2017-12-01

While some planetary scientists have extensive experience sharing their science with audiences, many can benefit from guidance on giving presentations or conducting activities for students. The Lunar and Planetary Institute (LPI) provides resources and trainings to support planetary scientists in their communication efforts. Trainings have included sessions for students and early career scientists at conferences (providing opportunities for them to practice their delivery and receive feedback for their poster and oral presentations), as well as separate communication workshops on how to engage various audiences. LPI has similarly begun coaching planetary scientists to help them prepare their public presentations. LPI is also helping to connect different audiences and their requests for speakers to planetary scientists. Scientists have been key contributors in developing and conducting activities in LPI education and public events. LPI is currently working with scientists to identify and redesign short planetary science activities for scientists to use with different audiences. The activities will be tied to fundamental planetary science concepts, with basic materials and simple modifications to engage different ages and audience size and background. Input from the planetary science community on these efforts is welcome. Current results and resources, as well as future opportunities will be shared.

Why School Students Choose and Reject Science: A Study of the Factors That Students Consider When Selecting Subjects

ERIC Educational Resources Information Center

Palmer, Tracey-Ann; Burke, Paul F.; Aubusson, Peter

2017-01-01

Student study of science at school has been linked to the need to provide a scientifically capable workforce and a scientifically literate society. Educators, scientists, and policymakers are concerned that too few students are choosing science for study in their final years of school. How and why students choose and reject certain subjects,…

High School Students' Attitudes Towards Spiders: A cross-cultural comparison

NASA Astrophysics Data System (ADS)

Prokop, Pavol; Tolarovičová, Andrea; Camerik, Anne M.; Peterková, Viera

2010-08-01

Spiders are traditionally considered to be among the least popular of animals. Current evidence suggests that a negative attitude towards spiders could be influenced by both cultural and evolutionary pressures. Some researchers suggest that science education activities could positively influence students' perceptions of spiders. Their evidence is, however, ambivalent. Using a five-point score Likert-type questionnaire in which the items were developed in a similar way to four of Kellert's categories of attitude (scientistic, negativistic, naturalistic, and ecologistic) towards invertebrates, we compared the level of knowledge of and attitudes towards spiders of high school students from two countries, Slovakia (n = 354) and South Africa (n = 382). The students represented different cultures and followed dissimilar science education curricula. Only among the Slovakian students there was a statistically significant but low correlation between knowledge and attitude (r = 0.30). The South African students scored higher in the categories of scientistic, naturalistic, and ecologistic attitudes. Comparison of attitude towards spiders of indigenous Africans from coeducational Catholic schools revealed that South African students have greater fear of spiders than Slovakian students, supporting the biological preparedness hypothesis. This hypothesis predicts a greater fear of spiders in South Africa than in Europe since several South African spiders possess venoms that are dangerous to humans. The results of this study are discussed from science education, cultural, and evolutionary perspectives.

Utilizing the Scientist as Teacher Through the Initiating New Science Partnerships in Rural Education (INSPIRE) Program

NASA Astrophysics Data System (ADS)

Pierce, D.; McNeal, K. S.; Radencic, S.

2011-12-01

The presence of a scientist or other STEM expert in secondary school science classroom can provide fresh new ideas for student learning. Through the Initiating New Science Partnerships in Rural Education (INSPIRE) program sponsored by NSF Graduate STEM Fellows in K-12 Education (GK-12), scientists and engineers at Mississippi State University work together with graduate students and area teachers to provide hands-on inquiry-based learning to middle school and high school students. Competitively selected graduate fellows from geosciences, physics, chemistry, and engineering spend ten hours per week in participating classrooms for an entire school year, working as a team with their assigned teacher to provide outstanding instruction in science and mathematics and to serve as positive role models for the students. We are currently in the second year of our five-year program, and we have already made significant achievements in science and mathematics instruction. We successfully hosted GIS Day on the Mississippi State University campus, allowing participating students to design an emergency response to a simulated flooding of the Mississippi Delta. We have also developed new laboratory exercises for high school physics classrooms, including a 3-D electric field mapping exercise, and the complete development of a robotics design course. Many of the activities developed by the fellows and teachers are written into formal lesson plans that are made publicly available as free downloads through our project website. All participants in this program channel aspects of their research interests and methods into classroom learning, thus providing students with the real-world applications of STEM principles. In return, participants enhance their own communication and scientific inquiry skills by employing lesson design techniques that are similar to defining their own research questions.

Exploring Natural and Social Scientists' Views of Nature of Science

ERIC Educational Resources Information Center

Bayir, Eylem; Cakici, Yilmaz; Ertas, Ozge

2014-01-01

Science education researchers recently turned their attention to exploring views about nature of science (NOS). A large body of research indicates that both students and teachers have many naïve views about the NOS. Unfortunately, less attention has been directed at the issue of exploring the views of the scientists. Also, the little research in…

The Ocean 180 Video Challenge: An Innovative Broader Impacts Strategy for Helping Scientists Share Discoveries and Connect with Classrooms

NASA Astrophysics Data System (ADS)

Tankersley, R. A.; Watson, M.; Windsor, J. G.; Buckley, M.; Diederick, L.

2014-12-01

Scientists conduct exciting, ground-breaking research that addresses many of world's greatest challenges. Yet, far too often, the importance, meaning, and relevance of their discoveries are never shared with persons outside their discipline. Recognizing the need for scientists to communicate more effectively with the public, the Florida Center for Ocean Sciences Education Excellence (COSEE Florida) saw an opportunity to connect the two through film. In the fall 2013, COSEE Florida launched the Ocean 180 Video Challenge to tap into the competitive spirit of scientists and inspire them to share their latest discoveries with the public. The competition encouraged scientists to submit short, 3-minute video abstracts summarizing the important findings of recent peer-reviewed papers and highlighting the relevance, meaning, and implications of the research to persons outside their discipline. Videos were initially screened and evaluated by a team of science and communication experts and the winners (from a field of ten finalists) were selected by more than 30,000 middle school students from 285 schools in 13 countries. Our presentation will review the outcomes and lessons learned from the 2014 competition and describe how contest videos are being used for professional development/training and educational purposes. We will also describe how video competitions can benefit both scientists and the target audience and be effective outreach strategies for encouraging scientists to share new discoveries and their enthusiasm for science with K-12 students and the public.

The GLOBE Program: Partnerships in Action

NASA Astrophysics Data System (ADS)

Henderson, S.; Kennedy, T.; Lemone, M.; Blurton, C.

2004-12-01

The GLOBE Program is a worldwide science and education partnership endeavor designed to increase scientific understanding of Earth as a system, support improved student achievement in science and math, and enhance environmental awareness through inquiry-based learning activities. GLOBE began on the premise that teachers and their students would partner with scientists to collect and analyze environmental data using specific protocols in five study areas - atmosphere, soils, hydrology, land cover, and phenology. As the GLOBE network grew, additional partnerships flourished making GLOBE an unprecedented collaboration of individuals worldwide - primary, secondary, and tertiary students, teachers and teacher educators, scientists, government officials, and others - to improve K-12 education. Since its inception in 1994, more than one million students in over 14,000 schools around the world have taken part in The GLOBE Program. The GLOBE Web site (http://www.globe.gov) is the repository for over 11 million student-collected data measurements easily accessible to students and scientists worldwide. Utilizing the advantages of the Internet for information sharing and communication, GLOBE has created an international community. GLOBE enriches students by giving them the knowledge and skills that they will need to become informed citizens and responsible decision-makers in an increasingly complex world. Understanding that all members of a community must support change if it is to be sustainable, GLOBE actively encourages the development of GLOBE Learning Communities (GLCs) which are designed to get diverse stakeholder groups involved in a local or regional environmental issue. Central to the GLC is the engagement of local schools. GLCs go beyond individual teachers implementing GLOBE in the isolation of their classrooms. Instead, the GLC brings multiple teachers and grade levels together to examine environmental issues encouraging the participation of a broad range of community members who share a common commitment to supporting teachers and students in the implementation of GLOBE for the benefit of their community. A GLC might begin as a GLOBE Partner based at a university works with teachers and students from primary and secondary schools in the local school district, and then branches out to include parents, youth clubs, scientists, senior citizens, other colleges and universities, daycare centers, museums, businesses, government agencies and more. In the past decade, as the variety and diversity of partnerships within the GLOBE Program expanded, lessons have been learned that may be of use to other programs intent on implementing partnership programs to sustain systemic changes in K-12 Earth Science Education. This presentation will chronicle the GLOBE journey including results of annual program evaluations.

Bridging the Gap Between Scientists and Classrooms: Scientist Engagement in the Expedition Earth and Beyond Program

NASA Technical Reports Server (NTRS)

Graff, P. V.; Stefanov, W. L.; Willis, K. J.; Runco, S.

2012-01-01

Teachers in today s classrooms need to find creative ways to connect students with science, technology, engineering, mathematics (STEM) experts. These STEM experts can serve as role models and help students think about potential future STEM careers. They can also help reinforce academic knowledge and skills. The cost of transportation restricts teachers ability to take students on field trips exposing them to outside experts and unique learning environments. Additionally, arranging to bring in guest speakers to the classroom seems to happen infrequently, especially in schools in rural areas. The Expedition Earth and Beyond (EEAB) Program [1], facilitated by the Astromaterials Research and Exploration Science (ARES) Directorate Education Program at the NASA Johnson Space Center has created a way to enable teachers to connect their students with STEM experts virtually. These virtual connections not only help engage students with role models, but are also designed to help teachers address concepts and content standards they are required to teach. Through EEAB, scientists are able to actively engage with students across the nation in multiple ways. They can work with student teams as mentors, participate in virtual student team science presentations, or connect with students through Classroom Connection Distance Learning (DL) Events.

Communicating Ocean Sciences to Informal Audiences (COSIA): Universities, Oceanographic Institutions, Science Centers and Aquariums Working Together to Improve Ocean Education and Public Outreach

NASA Astrophysics Data System (ADS)

Glenn, S.; McDonnell, J.; Halversen, C.; Zimmerman, T.; Ingram, L.

2007-12-01

Ocean observatories have already demonstrated their ability to maintain long-term time series, capture episodic events, provide context for improved shipboard sampling, and improve accessibility to a broader range of participants. Communicating Ocean Sciences, an already existing college course from COSEE-California has demonstrated its ability to teach future scientists essential communication skills. The NSF-funded Communicating Ocean Sciences to Informal Audiences (COSIA) project has leveraged these experiences and others to demonstrate a long-term model for promoting effective science communication skills and techniques applicable to diverse audiences. The COSIA effort is one of the pathfinders for ensuring that the new scientific results from the increasing U.S. investments in ocean observatories is effectively communicated to the nation, and will serve as a model for other fields. Our presentation will describe a long-term model for promoting effective science communication skills and techniques applicable to diverse audiences. COSIA established partnerships between informal science education institutions and universities nationwide to facilitate quality outreach by scientists and the delivery of rigorous, cutting edge science by informal educators while teaching future scientists (college students) essential communication skills. The COSIA model includes scientist-educator partnerships that develop and deliver a college course that teaches communication skills through the understanding of learning theory specifically related to informal learning environments and the practice of these skills at aquariums and science centers. The goals of COSIA are to: provide a model for establishing substantive, long-term partnerships between scientists and informal science education institutions to meet their respective outreach needs; provide future scientists with experiences delivering outreach and promoting the broader impact of research; and provide diverse role models and inquiry-based ocean sciences activities for children and families visiting informal institutions. The following COSIA partners have taught the course: Hampton University - Virginia Aquarium; Oregon State University - Hatfield Marine Science Visitor's Center; Rutgers University - Liberty Science Center; University of California, Berkeley - Lawrence Hall of Science; University of Southern California - Aquarium of the Pacific; and Scripps Institution of Oceanography - Birch Aquarium. Communicating Ocean Sciences has also been taught at Stanford, Woods Hole Oceanographic Institute, University of Oregon (GK-12 program), University of Washington, and others. Data from surveys of students demonstrates improvement in their understanding of how people learn and how to effectively communicate. Providing college students with a background in current learning theory, and applying that theory through practical science communication experiences, will empower future generations of scientists to meet the communication challenges they will encounter in their careers.

Moral reasoning about great apes in research

NASA Astrophysics Data System (ADS)

Okamoto, Carol Midori

2006-04-01

This study explored how individuals (biomedical scientists, Great Ape Project activists, lay adults, undergraduate biology and environmental studies students, and Grade 12 and 9 biology students) morally judge and reason about using great apes in biomedical and language research. How these groups perceived great apes' mental capacities (e.g., pain, logical thinking) and how these perceptions related to their judgments were investigated through two scenarios. In addition, the kinds of informational statements (e.g., biology, economics) that may affect individuals' scenario judgments were investigated. A negative correlation was found between mental attributions and scenario judgments while no clear pattern occurred for the informational statements. For the biomedical scenario, all groups significantly differed in mean judgment ratings except for the biomedical scientists, GAP activists and Grade 9 students. For the language scenario, all groups differed except for the GAP activists, and undergraduate environmental studies and Grade 9 students. An in-depth qualitative analysis showed that although the biomedical scientists, GAP activists and Grade 9 students had similar judgments, they produced different mean percentages of justifications under four moral frameworks (virtue, utilitarianism, deontology, and welfare). The GAP activists used more virtue reasoning while the biomedical scientists and Grade 9 students used more utilitarian and welfare reasoning, respectively. The results are discussed in terms of developing environmental/humane education curricula.

Challenging 21st Century Students to Take the Step-By-Step Approach to a Scientific Investigation by Incorporating Interactive Multimedia Events with a Real Scientist.

NASA Astrophysics Data System (ADS)

Delaney, M. P.; Hoban, S.

2006-12-01

Rousing students to go beyond the textbook and apply science inquiry skills is one of the most difficult tasks of today`s teacher. Moreover, finding valuable inquiry-based activities that will interest a student can also be daunting. The NASA Exploring Space Challenges was developed last year to provide middle school teachers with an opportunity to get their students involved in real scientific investigations. The framework of the Challenges is not to just give a teacher an activity and leave it to their own timetables to perform in the classroom, if at all. Rather, teachers are provided with an activity with hands-on training, interactivity for their students with a real scientist and a strict timeline students must adhere to. The Challenges model requires students to emulate the same procedures as a scientist when conducting a research project. Students first design a project, submit a short proposal, receive feedback, then conduct an investigation by collecting real data. Students can then ground-truth their results by researching data that may already exist in similar context. Finally, students present their findings to a panel, just as a real scientist would at a professional conference. The activity is taken one step further by providing students with lessons on basic measurement and data collecting skills through a series of videoconferences. The golden carrot, however, is the incentive of a competition. Students have an opportunity to give their oral presentation to a panel of NASA scientists and educators. This format has been a huge success. For example, we found that students are more productive, often due to the need to impress the scientist during a videoconference. Students and teachers are also forced to use technology often under-utilized during the typical school day. We also found that teachers are given access to additional support during the activity, through the videoconferencing events or outside communication. Most importantly, teachers are provided with validation. Teachers report that their students "finally believe in them" if the same information is provided by a real scientist. An added bonus we found is that at the end, more students are inclined to consider a STEM career.

Connecting Teachers and Students with Science Experts: NASA's Expedition Earth and Beyond Program

NASA Astrophysics Data System (ADS)

Graff, P. V.; Stefanov, W. L.; Willis, K. J.; Runco, S.; McCollum, T.; Baker, M.; Mailhot, M.; Lindgren, C. F.

2010-12-01

Classroom teachers are challenged with engaging and preparing today’s students for the future. Activities are driven by state required skills, education standards, and high stakes testing. How can educators teach required standards and motivate students to not only learn essential skills, but also acquire a sense of intrigue to want to learn more? One way is to allow students to take charge of their learning and conduct student-driven research. NASA’s Expedition Earth and Beyond program, based at the NASA Johnson Space Center, is designed to do just that. The program, developed by both educators and scientists, promotes inquiry-based investigations in classrooms (grades 5-14) by using current NASA data. By combining the expertise of teachers, who understand the everyday challenges of working with students, and scientists, who work with the process of science as they conduct their own research, the result is a realistic and useable means in which to promote authentic research in classrooms. NASA’s Expedition Earth and Beyond Program was created with the understanding that there are three important aspects that enable teachers to implement authentic research experiences in the classroom. These aspects are: 1) Standards-aligned, inquiry based curricular resources and an implementation structure to support student-driven research; 2) Professional development opportunities to learn techniques and strategies to ensure seamless implementation of resources; and 3) Ongoing support. Expedition Earth and Beyond provides all three of these aspects and adds two additional and inspiring motivators. One is the opportunity for student research teams to request new data. Data requested and approved would be acquired by astronauts orbiting Earth on the International Space Station. This aspect is part of the process of science structure and provides a powerful way to excite students. The second, and perhaps more significant motivator, is the creation of connections between science experts and classrooms. Scientists are able to connect with participating classrooms on a variety of different levels, including being a mentor. These powerful connections provide extraordinary opportunities for students to develop the rigor and relevance of their research, along with encouraging them to have a sense of pride in the work they are doing in school. Providing teachers with skills and the confidence to promote authentic research investigations in the classroom will equip them to create science literate students, and by extension, improve the public understanding of science. The opportunity to connect classrooms with science experts creates personal experiences that are engaging, motivating and impactful. These impactful experiences will help prepare today’s students to become the next generation of scientists or perhaps science educators who can help continue these powerful connections for generations to come.

Engaging Medical Students in Research: Reaching out to the Next Generation of Physician-Scientists

PubMed Central

Cluver, Jeffrey S.; Book, Sarah W.; Brady, Kathleen T.; Thornley, Nicola; Back, Sudie E.

2013-01-01

Objective The authors describe a multifaceted educational training approach aimed at increasing medical student involvement in psychiatric research. Method A description of the initiative is provided, including the rationale and expected impact of each component. Results Medical student involvement in research projects has increased steadily since implementation. This applies to summer research projects as well as elective research rotations for senior medical students. Furthermore, a substantial proportion of students who participate in research continue to engage in research activities following completion of the program (e.g., through additional research participation, conference presentations). Conclusion A proactive and well-organized approach to encouraging medical student participation in research can increase the number of students who choose to engage in a research and may ultimately help increase the number of physician-scientists. PMID:24913099

Becoming a Scientist: Research Findings on STEM Students' Gains from Conducting Undergraduate Research

NASA Astrophysics Data System (ADS)

Hunter, A.; Laursen, S.; Thiry, H.; Seymour, E.

2006-12-01

Undergraduate research is widely believed to enhance STEM students' education and increase their persistence to graduate education and careers in the sciences. Yet until very recently, little evidence from research and evaluation studies was available to substantiate such claims and document what students gain from doing undergraduate research or how these gains come about. We have conducted a three-year qualitative research study of STEM students participating in UR at four liberal arts colleges with a strong tradition of faculty-led summer research apprenticeships. Benefits to students reported by both students and their faculty advisors are categorized into six main categories of gains in skills, knowledge, "thinking like a scientist," career preparation, career development, and personal and professional growth. Student and faculty observations are strongly corroborative, but also differ in interesting ways that reflect the distinct perspectives of each group: students are still in the midst of discovering their own career paths while faculty advisors have observed the later career development of their past research students. While not all students find UR to heighten their interest in graduate school, they do find it a powerful growth experience that clarifies their career ambitions by providing a "real world" experience of science. For students whose interest in science is reinforced, UR has a significant role in their professional socialization into the culture and norms of science, which we call "becoming a scientist," through interactions that draw them into the scientific community and experiences that deepen their understanding of the nature of research. Cumulatively, the qualitative data set of nearly 350 interviews offers a rich portrayal of the UR enterprise from a variety of perspectives. Longitudinal data enable us to track the influence of UR on students' career and education trajectories in the years after college, and comparative data from a group of students who did not undertake UR or pursued alternate experiences reveal the extent to which some benefits of UR may be derived from other experiences. Faculty interviews reveal the costs and benefits to faculty of participating in this intensive form of science education. The presentation will highlight key findings and emphasize their relevance to faculty and program directors undertaking UR or seeking to generate its benefits through other activities.

Next Generation Science Partnerships

NASA Astrophysics Data System (ADS)

Magnusson, J.

2016-02-01

I will provide an overview of the Next Generation Science Standards (NGSS) and demonstrate how scientists and educators can use these standards to strengthen and enhance their collaborations. The NGSS are rich in content and practice and provide all students with an internationally-benchmarked science education. Using these state-led standards to guide outreach efforts can help develop and sustain effective and mutually beneficial teacher-researcher partnerships. Aligning outreach with the three dimensions of the standards can help make research relevant for target audiences by intentionally addressing the science practices, cross-cutting concepts, and disciplinary core ideas of the K-12 science curriculum that drives instruction and assessment. Collaborations between researchers and educators that are based on this science framework are more sustainable because they address the needs of both scientists and educators. Educators are better able to utilize science content that aligns with their curriculum. Scientists who learn about the NGSS can better understand the frameworks under which educators work, which can lead to more extensive and focused outreach with teachers as partners. Based on this model, the International Ocean Discovery Program (IODP) develops its education materials in conjunction with scientists and educators to produce accurate, standards-aligned activities and curriculum-based interactions with researchers. I will highlight examples of IODP's current, successful teacher-researcher collaborations that are intentionally aligned with the NGSS.

Text-based plagiarism in scientific writing: what Chinese supervisors think about copying and how to reduce it in students' writing.

PubMed

Li, Yongyan

2013-06-01

Text-based plagiarism, or textual copying, typically in the form of replicating or patchwriting sentences in a row from sources, seems to be an issue of growing concern among scientific journal editors. Editors have emphasized that senior authors (typically supervisors of science students) should take the responsibility for educating novices against text-based plagiarism. To address a research gap in the literature as to how scientist supervisors perceive the issue of textual copying and what they do in educating their students, this paper reports an interview study with 14 supervisors at a research-oriented Chinese university. The study throws light on the potentiality of senior authors mentoring novices in English as an Additional Language (EAL) contexts and has implications for the efforts that can be made in the wider scientific community to support scientists in writing against text-based plagiarism.

Developing Effective K-16 Geoscience Research Partnerships.

ERIC Educational Resources Information Center

Harnik, Paul J.; Ross, Robert M.

2003-01-01

Discusses the benefits of research partnerships between scientists and K-16 students. Regards the partnerships as effective vehicles for teaching scientific logic, processes, and content by integrating inquiry-based educational approaches with innovative research questions. Reviews integrated research and education through geoscience partnerships.…

Matriculating Masculinity: Understanding Undergraduate Men's Precollege Gender Socialization

ERIC Educational Resources Information Center

Harris, Frank, III; Harper, Shaun R.

2015-01-01

Social scientists, educational researchers, postsecondary educators (including student affairs professionals), and others have attempted to understand problematic behavioral trends and developmental outcomes among undergraduate men. Little attention has been devoted to examining the masculine identities and ideals about manhood that these students…

Research goes to School: understanding the content and the procedures of Science through a new dialogue among students, teachers and scientists

NASA Astrophysics Data System (ADS)

L'Astorina, Alba; Tomasoni, Irene

2015-04-01

The Education system is increasingly interested in a more interactive dialogue with scientists in order to make science taught at school more aware of the models and the ways in which knowledge is produced, revised and discussed within the scientific community. Not always, in fact, the ministerial programs, the media, and the textbooks adopted by schools seem to be able to grasp the content and the procedures of the scientific knowledge as it is today being developed, sometimes spreading the idea of a monolithic and static science, with no reference to revisions, uncertainties, errors and disputes that, on the opposite, characterize the debate about science. On the other side, scientists, that in several surveys define students and teachers as one of the key groups that are most important to communicate with, often do not seem to be aware that scientific knowledge is continuously revised by the school and its protagonists. Science teaching, in all classes, has a highly educational role, as it offers the opportunity to value individual differences, to make students acquire specific tools and methods that enable them understand the world and critically interact with it. In this process of conscious learning, in which teachers play the role of tutors, the student participates actively bringing his tacit knowledge and beliefs. In this context, an educational proposal has recently been developed by the Italian National Research Council (CNR), aimed at starting a new dialogue between Education and Research. It's a way to encourage the technical and scientific culture among young people and a mutual exchange between the two main actors of the scientific production and promotion, considering weaknesses and strengths of the relationship between these two systems. In this proposal, students and teachers follow side by side a group of CNR scientists involved in an ongoing research project based on the use of innovative methodologies of aerospace Earth Observation (EO) for supporting the agricultural sector in Italy. A research project has its own planning and timing in which objectives, activities, tools and results are scheduled, monitored and evaluated; following its steps means understanding the content and the procedures of applied research, that has to face not only with scientific and technological but also with administrative, financial, communication aspects. In this process, scientists interact with several actors in addiction to the scientific community, such as private and public stakeholders, users, policy makers, media and the general public. The proposal involves for 2 years 10 teachers and 160 high school students in several activities: an opening participative workshop in which students and scientists exchange ideas and expectations on Research and Education and try to delineate the possible relationship between the two systems; personalized laboratories during which every School, according to its field of study, deepens one of the 3 specific research areas of the project, i.e. Earth Observation, use of UAV/drones, VGI and smart technologies for acquisition and distribution of field data through a Geoportal. In the last step, students and researchers plan and implement together some of the projects' task and a final event. At EGU the first results and further developments of the proposal will be highlighted.

Scientists as Correspondents: Exploratorium "Ice Stories" for International Polar Year Project Educational Outreach

NASA Astrophysics Data System (ADS)

McGillivary, P. A.; Fall, K. R.; Miller, M.; Higdon, R.; Andrews, M.; O'Donnell, K.

2008-12-01

As part of the 2007-2009 International Polar Year (IPY), an educational outreach developed by the Exploratorium science museum of San Francisco builds on prior high latitude programs to: 1) create public awareness of IPY research; 2) increase public understanding of the scientific process; and, 3) stimulate a new relationship between scientists and outreach. Funded by the National Science Foundation, a key "Ice Stories" innovation is to facilitate "scientist correspondents" reporting directly to the public. To achieve this, scientists were furnished multimedia equipment and training to produce material for middle school students to adults. Scientists submitted blogs of text, images, and video from the field which were edited, standardized for format, and uploaded by Exploratorium staff, who coordinated website content and management. Online links to educational partner institutions and programs from prior Exploratorium high latitude programs will extend "Ice Stories" site visits beyond the @250,000 unique in-house users/year to more than 28 million webpage users/year overall. We review relevant technical issues, the variety of scientist participation, and what worked best and recommendations for similar efforts in the future as a legacy for the IPY.

In the Footsteps of Roger Revelle: A STEM Partnership Between Scripps Institution of Oceanography, Office of Naval Research and Middle School Science Students Bringing Next Generation Science Standards into the Classroom through Ocean Science

NASA Astrophysics Data System (ADS)

Brice, D.; Appelgate, B., Jr.; Mauricio, P.

2014-12-01

Now in its tenth year, "In the Footsteps of Roger Revelle" (IFRR) is a middle school science education program that draws student interest, scientific content and coherence with Next Generation Science Standards from real-time research at sea in fields of physical science. As a successful collaboration involving Scripps Institution of Oceanography (SIO),Office of Naval Research (ONR), and San Marcos Middle School (SMMS), IFRR brings physical oceanography and related sciences to students at the San Marcos Middle School in real-time from research vessels at sea using SIO's HiSeasNet satellite communication system. With a generous grant from ONR, students are able to tour the SIO Ships and spend a day at sea doing real oceanographic data collection and labs. Through real-time and near-realtime broadcasts and webcasts, students are able to share data with scientists and gain an appreciation for the value of Biogeochemical research in the field as it relates to their classroom studies. Interaction with scientists and researchers as well as crew members gives students insights into not only possible career paths, but the vital importance of cutting edge oceanographic research on our society. With their science teacher on the ship as an education outreach specialist or ashore guiding students in their interactions with selected scientists at sea, students observe shipboard research being carried out live via videoconference, Skype, daily e-mails, interviews, digital whiteboard sessions, and web interaction. Students then research, design, develop, deploy, and field-test their own data-collecting physical oceanography instruments in their classroom. The online interactive curriculum models the Next Generation Science Standards encouraging active inquiry and critical thinking with intellectually stimulating problem- solving, enabling students to gain critical insight and skill while investigating some of the most provocative questions of our time, and seeing scientists as role-models. IFRR has provided students in the San Diego area with a unique opportunity for learning about oceanographic research, which could inspire students to become oceanographers or at least scientifically literate citizens, a benefit for our society at large.

Education Highlights: Synthetic Nanoparticles

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

Gambacorta, Francesca; Michalska, Martyna

Argonne intern Francesca Gambacorta from University of Illinois at Urbana–Champaign worked with Argonne mentor Phil Laible and Postdoctoral mentor Martyna Michalska to study how black silicon, a synthetic nanomaterial, kills bacteria. This research will help scientists predict other applications of this material in the biomedical field. Argonne aims to develop the next generation of scientists, researchers, and engineers by mentoring over 300 undergraduate and graduate students a year from over 40 STEM majors in over 15 different career development programs. Students come from over 160 colleges and universities in 41 states and 15 countries.

The pupils of L.P. Ginsburg - The graduates of the faculty of mathematics and mechanics of Leningrad State University

NASA Astrophysics Data System (ADS)

Matveev, S. K.; Arkhangelskaya, L. A.; Akimov, G. A.

2018-05-01

Isaak Pavlovich Ginzburg (1910-1979) was a professor at the hydroaeromechanics department of Leningrad State University, a prominent scientist, an outstanding organizer and a brilliant educator, who had trained more than one generation of specialists in the field of fluid, gas and plasma mechanics. Many of his students became major scientists and organizers of science. The present paper is devoted to the students of I.P. Ginzburg graduated from the Mathematics and Mechanics Faculty of Leningrad State University.

Scaffolded Inquiry-Based Instruction with Technology: A Signature Pedagogy for STEM Education

ERIC Educational Resources Information Center

Crippen, Kent J.; Archambault, Leanna

2012-01-01

Inquiry-based instruction has become a hallmark of science education and increasingly of integrated content areas, including science, technology, engineering, and mathematics (STEM) education. Because inquiry-based instruction very clearly contains surface, deep, and implicit structures as well as engages students to think and act like scientists,…

Methodology of a Modern Foreign Language Lesson for Postgraduate Students of Technical Disciplines

ERIC Educational Resources Information Center

Toporkova, Olga; Novozhenina, Elena; Tchechet, Tamara; Likhacheva, Tatiana

2014-01-01

The integration of Russia into the international common space of research and education accompanied by modernization of the national system of education puts forward new demands to postgraduate education. The processes of integration and modernization increase the importance of learning a foreign language for a future scientist. The article deals…

Biology Faculty at Large Research Institutions: The Nature of Their Pedagogical Content Knowledge

ERIC Educational Resources Information Center

Hill, Kathleen M.

2013-01-01

To address the need of scientists and engineers in the United States workforce and ensure that students in higher education become scientifically literate, research and policy has called for improvements in undergraduate education in the sciences. One particular pathway for improving undergraduate education in the science fields is to reform…

A Community of Scientists and Educators: The Compass Project at UC Berkeley

NASA Astrophysics Data System (ADS)

Roth, Nathaniel; Schwab, Josiah

2016-01-01

The Berkeley Compass Project is a self-formed group of graduate and undergraduate students in the physical sciences at the University of California, Berkeley. Its goals are to improve undergraduate physics education, provide opportunities for professional development, and increase retention of students from populations underrepresented in the physical sciences. For undergraduate students, the core Compass experience consists of a summer program and several seminar courses. These programs are designed to foster a diverse, collaborative student community in which students engage in authentic research practices and regular self-reflection. Graduate students, together with upper-level undergraduates, design and run all Compass programs. Compass strives to incorporate best practices from the science education literature. Experiences in Compass leave participants poised to be successful students researchers, teachers, and mentors.

The effect of historical, non-fiction, trade books on third-grade students' perceptions of scientists

NASA Astrophysics Data System (ADS)

Farland, Donna Lynn

Researchers do not know what, if any, specific influence such stereotypical images have on the shaping of children's perceptions in science (Schibeci & Sorenson, 1983), but the indications are that stereotypical images translate into negative perceptions of science. Commonly held stereotypic images are in direct opposition to what students should understand about science as identified by the National Science Education Standards (1996) in which learning about 'Science as a Human Endeavor' begins as early as grades K--4. Nationally, many schools are moving toward kit-based science instruction, which generally consists of a series of guided discovery activities that lead children toward description and understanding of scientific phenomena. It is proposed that by supplementing these kits with historical, non-fiction, trade books, children will gain a broader understanding of the diversity of scientists, their work, and the variety of places science is done. No studies, to date, have been conducted to examine students' understanding of the concepts included in 'Science as a Human Endeavor' as they receive kit-based science instruction. This research has been designed to answer the following question: Does the inclusion of historical, non-fiction, trade books, presenting scientists as people working with or developing an idea, as part of kit-based science instruction influence third grade students' representations of the contemporary scientist and his/her work? It was found that students who were read historical, non-fiction, trade books in conjunction with kit-based instruction demonstrated significant differences in their drawings of scientists from those produced by students who were not exposed to the trade books with respect to two criteria; appearance of scientists, and the activity performed by scientists. This study also revealed that students were able to maintain the improvement in their representations of scientists four weeks after the intervention had ended. This study indicates that there is a need for explicit teaching of the concepts of 'Science as a Human Endeavor'. It is suggested that historical, non-fiction, trade books provide the means by which third grade students gain a broader understanding of who does science and what their work involves. (Abstract shortened by UMI.)

The International Polar Year in Portugal: A New National Polar Programme and a Major Education and Outreach project

NASA Astrophysics Data System (ADS)

Mendes-Victor, L.; Vieira, G.; Xavier, J.; Canario, A.

2008-12-01

Before the International Polar Year, in Portugal polar research was conducted by a very small group of scientists integrated in foreign projects or research institutions. Portugal was not member of the Scientific Committee for Antarctic Research (SCAR), the European Polar Board (EPB), neither a subscriber of the Antarctic Treaty. In 2004 Portuguese Polar researchers considered the IPY as an opportunity to change this situation and organized the national Committee for the IPY. The objectives were ambitious: to answer the aforementioned issues in defining and proposing a National Polar Programme. In late 2008, close to the end of the IPY, the objectives were attained, except the Antarctic Treaty signature that is, however, in an advanced stage, having been approved by consensus at the National Parliament in early 2007. Portugal joined SCAR in July 2006, the EPB in 2007 and a set of 5 Antarctic research projects forming the roots of the National Polar Programme (ProPolar) have been approved by the Foundation for Science and Technology (FCT-MCTES). Scientifically, the IPY can already be considered a major success in Portugal with an improvement in polar scientific research, in the number of scientists performing field work in the Antarctic, organizing polar science meetings and producing an expected increase in the number of polar science peer- reviewed papers. The Portuguese IPY scientific activities were accompanied by a major education and outreach project funded by the Agencia Ciência Viva (MCTES): LATITUDE60! Education for the Planet in the IPY. This project lead by the universities of Algarve, Lisbon and by the Portuguese Association of Geography Teachers is heavily interdisciplinary, programmed for all ages, from kindergarten to adults, and hoped to bring together scientists and society. LATITUDE60! was a major success and focussed on showing the importance of the polar regions for Earth's environment, emphasising on the implications of polar change for Portuguese society. Hundreds of events were organized, with activities lead by polar scientists and by about 400 teachers and thousands of students that got deeply involved in the IPY. The main activities were: the scientists go to school initiative, a national contest with over 8,000 participants that lead to a major exhibition and to the participation of 7 students in the Students on Ice Antarctic Expedition, an educational theatre play for kids presented n tens of schools, an IPY exhibition in the major shopping centers, public talks by scientists, production of educational materials (websites, a polar portal, on-line educational games, DVDs and class-oriented material), field stages with polar scientists, and the Polar Science Weekend with an attendance of over 7,000 people.

Students Inspiring Students: An Online Tool for Science Fair Participants

ERIC Educational Resources Information Center

Seeman, Jeffrey I.; Lawrence, Tom

2011-01-01

One goal of 21st-century education is to develop mature citizens who can identify issues, solve problems, and communicate solutions. What better way for students to learn these skills than by participating in a science and engineering fair? Fair participants face the same challenges as professional scientists and engineers, even Nobel laureates.…

Introducing Taiwanese Undergraduate Students to the Nature of Science through Nobel Prize Stories

ERIC Educational Resources Information Center

Eshach, Haim; Hwang, Fu-Kwun; Wu, Hsin-Kai; Hsu, Ying-Shao

2013-01-01

Although there is a broad agreement among scientists and science educators that students should not only learn science, but also acquire some sense of its nature, it has been reported that undergraduate students possess an inadequate grasp of the nature of science (NOS). The study presented here examined the potential and effectiveness of Nobel…

A Window on Science: Exploring the JASON Project and Student Conceptions of Science.

ERIC Educational Resources Information Center

Moss, David M.

2003-01-01

Describes how the JASON project was implemented in a self-contained 4th grade classroom and examines this project within the overall context of student-scientist partnership (SSP) models of science education reform. Examines changes in student conceptions of the nature of science as a result of participating in science. (Contains 24 references.)…

Teaching Young Scientists about Their Bodies

ERIC Educational Resources Information Center

Ashbrook, Peggy

2012-01-01

Early childhood educators contribute to the good health of their students every day. By telling students, "Wash your hands" and "Eat your healthy food first," and providing them time to develop gross motor skills through active play outdoors, teachers hope that students will take the advice with them on the way to a healthy and active lifestyle.…

Developing Students' Ideas about Lens Imaging: Teaching Experiments with an Image-Based Approach

ERIC Educational Resources Information Center

Grusche, Sascha

2017-01-01

Lens imaging is a classic topic in physics education. To guide students from their holistic viewpoint to the scientists' analytic viewpoint, an image-based approach to lens imaging has recently been proposed. To study the effect of the image-based approach on undergraduate students' ideas, teaching experiments are performed and evaluated using…

Partnership with informal education learning centers to develop hands-on activities for research outreach efforts

NASA Astrophysics Data System (ADS)

Courville, Z.; Haynes, R.; DeFrancis, G.; Koh, S.; Ringelberg, D.

2012-12-01

Outreach informed by scientific research plays an important role in fostering interest in science by making science and scientists accessible, fun, and interesting. Developing an interest in science in young, elementary-aged students through outreach is a rewarding endeavor for researchers, in that audiences are usually receptive, requirements for broader impacts are met, and bonds are formed between researchers and members of their local and surrounding communities. Promoting such interest among young students is imperative not only for an individual researcher's own self interest, but also for the strength of American science and innovation moving forward, and is the responsibility of the current generation of scientists. Developing genuine and successful inquiry-based, hands-on activities for elementary-aged students is outside the expertise of many researchers. Partnering with an informal education learning center (i.e. science museum or after-school program) provides researchers with the expertise they might be lacking in such endeavors. Here, we present a series of polar-, engineering- and microbiology-themed hands-on activities that have been developed by researchers at a government lab in partnership with a local science museum. Through a series of workshops, the science education staff at the museum provided researchers with background and instruction on inquiry and hands-on activities, and then collaborated with the researchers to develop activities which were later demonstrated at the museum to museum-goers. Education staff provided feedback about the presentation of the activities for further refinement. The program provided an opportunity for researchers to develop fun, on-target and age-appropriate science activities for elementary-aged students, an audience for outreach, and enabled general public audiences the chance to interact with researchers and scientists in an informal setting.

"Teaching Physics as one of the humanities": The history of (harvard) project Physics, 1961-1970

NASA Astrophysics Data System (ADS)

Meshoulam, David

In the United States after World War II, science had come to occupy a central place in the minds of policy makers, scientists, and the public. Negotiating different views between these groups proved a difficult task and spilled into debates over the role and scope of science education. To examine this process, this dissertation traces the history of Harvard Project Physics (HPP), a high-school physics curriculum from the 1960s that incorporated a humanistic and historical approach to teaching science. The narrative begins with the rise of General Education in the 1940s. Under the leadership of Harvard president James Conant, faculty at Harvard developed several Natural Science courses that connected science to history as a way to teach students about science and its relationship to culture. By the late 1950s this historical approach faced resistance from scientists who viewed it as misrepresenting their disciplines and called for students to learn specialized subject matter. With the support of the National Science Foundation (NSF), in the early 1960s scientists' vision of science education emerged in high-school classrooms across the country. By the mid 1960s, with the passage of the Civil Rights Act, the Elementary and Secondary Education Act, and the Daddario Amendment to the NSF, the political and education landscape began to change. These laws transformed the goals of two of the NSF and the Office of Education (USOE). These organizations faced demands to work together to develop projects that would speak to domestic concerns over equity and diversity. Their first joint educational venture was HPP. In order to succeed, HPP had to speak to the needs of disciplinary-minded scientists at the NSF, equity-minded educators at the USOE, and results-focused politicians in Congress. This work argues that HPP succeeded because it met the needs of these various stakeholders regarding the roles of science and education in American society.

People behind the Science

ERIC Educational Resources Information Center

Kruse, Jerrid; Borzo, Sarah

2010-01-01

In addition to meeting National Science Education Standards (NSES) related to the history and nature of science (NOS), reading or hearing about real scientists helps students connect with science emotionally. The authors have even noticed increased student interest in science concepts during history of science discussions. Toward these efforts,…

Rethinking What Motivates and Inspires Students

ERIC Educational Resources Information Center

Bowman, Richard

2011-01-01

Drawing on four decades of scientific research on human motivation, contemporary behavioral scientists contend that exceptional educators provide students with a contextual sense of their intrinsic worth by creating academic environments that engage three overarching human needs: "autonomy," the freedom to make choices and determine one's future;…

Precipitation Education: Connecting Students and Teachers with the Science of NASA's GPM Mission

NASA Astrophysics Data System (ADS)

Weaver, K. L. K.

2015-12-01

The Global Precipitation Measurement (GPM) Mission education and communication team is involved in variety of efforts to share the science of GPM via hands-on activities for formal and informal audiences and engaging students in authentic citizen science data collection, as well as connecting students and teachers with scientists and other subject matter experts. This presentation will discuss the various forms of those efforts in relation to best practices as well as lessons learned and evaluation data. Examples include: GPM partnered with the Global Observations to Benefit the Environment (GLOBE) Program to conduct a student precipitation field campaign in early 2015. Students from around the world collected precipitation data and entered it into the GLOBE database, then were invited to develop scientific questions to be answered using ground observations and satellite data available from NASA. Webinars and blogs by scientists and educators throughout the campaign extended students' and teachers' knowledge of ground validation, data analysis, and applications of precipitation data. To prepare teachers to implement the new Next Generation Science Standards, the NASA Goddard Earth science education and outreach group, led by GPM Education Specialists, held the inaugural Summer Watershed Institute in July 2015 for 30 Maryland teachers of 3rd-5th grades. Participants in the week-long in-person workshop met with scientists and engineers at Goddard, learned about NASA Earth science missions, and were trained in seven protocols of the GLOBE program. Teachers worked collaboratively to make connections to their own curricula and plan for how to implement GLOBE with their students. Adding the arts to STEM, GPM is producing a comic book story featuring the winners of an anime character contest held by the mission during 2013. Readers learn content related to the science and technology of the mission as well as applications of the data. The choice of anime/manga as the style for the comic book reflects the international and cross-cultural aspect of the GPM as a joint mission between NASA and the Japan Aerospace Exploration Agency. A limited run print version of the initial comic book is planned for Fall 2015, with an online version and supplemental resources such as a teacher guide available on the GPM education website.

Attitudes toward Invertebrates: Are Educational "Bug Banquets" Effective?

ERIC Educational Resources Information Center

Looy, Heather; Wood, John R.

2006-01-01

Scientists have used educational presentations and "bug banquets" to alter widespread negative attitudes toward invertebrates. In this article, the authors explore whether such presentations have a measurable affect on attitudes. Junior high, high school, and university students completed an attitude survey focusing on invertebrates in…

Engaged Service Learning--Implications for Higher Education

ERIC Educational Resources Information Center

Webb, Tony; Burgin, Shelley

2009-01-01

Dwindling resources for tertiary education, has resulted in reduced emphasis on intensive, small group, staff-student collaborative project-based service learning. However, training scientists to manage significant issues, such as sustainable water use, requires an ability to engage both industry and community stakeholders. This paper describes…

SCUBAnauts International: Exploration and Discovery in the Ocean Sciences

NASA Astrophysics Data System (ADS)

Moses, C. S.; Palandro, D.; Coble, P.; Hu, C.

2007-12-01

The SCUBAnauts International program originated in 2001, as a 501(c)(3) non-profit organization designed to increase the attraction to science and technology careers in today's youth. SCUBAnauts International (SNI) consists of a diverse group of 12 to 18 year-old young men and women mentored by academic, federal, and state research scientists in an informal education environment. The program's mission is to promote interest in science and technology topics and careers by involving secondary education students as young explorers in the marine sciences and research activities, such as special environmental and undersea conservation projects that educate, promote active citizenship, and develop effective leadership skills. With help from mentors, SNI students collect and interpret research-quality data to meet the needs of ocean scientists, maintaining direct interaction between the scientists and the young men and women in the program. The science component of the program includes collection of benthic habitat, water quality, optics, and coral reef health data. During the school year, the SCUBAnauts are tasked with sharing their experiences to raise the environmental awareness of a larger audience by providing education outreach in formal and informal venues. Here we highlight results from recent SNI activities including data collection and program methodologies, and discuss future plans for the program.

The Effectiveness of the AAS REU Program

NASA Astrophysics Data System (ADS)

Hemenway, M. K.; Boyce, P. B.; Milkey, R. W.

1996-05-01

In an attempt to address the particular needs of astronomy faculty and undergraduate students, in 1991 the Education Office of the American Astronomical Society approached the National Science Foundation with a unique proposal for funding through the Research Experiences for Undergraduates program. The goals of the AAS program were to "slow the hemorrhage of students out of science...", extend the REU program to non-NSF-funded scientists, to reach under-represented women and minority students particularly in small educational institutions, and to encourage research scientists there to mentor students. As this grant has now expired, the AAS has surveyed the 44 mentors and their students to assess the program's effect on the mentor and the mentor's career; the educational institution; and the student's education and career choices. More than half the mentors responded by the abstract deadline. The program clearly had an effect upon the individuals involved. The greatest effect (in 85% of the cases) was to develop more interest in the mentor's research project both among the students and among the mentor's faculty colleagues. The mentors rated the grant to be a medium or strong factor in their student's decision to pursue graduate study, which 90% of them did. All but one of the AAS-REU students attended an AAS meeting and 3/4 of those gave a paper on their project research. Over 90% of the mentors felt that the research experience strongly promoted a greater interest in science, a greater understanding of science and a desire to continue in science. According to the mentors, this was a very positive and beneficial program for the students as well as for themselves.

Toward citizenship science education: what students do to make the world a better place?

NASA Astrophysics Data System (ADS)

Vesterinen, Veli-Matti; Tolppanen, Sakari; Aksela, Maija

2016-01-01

With increased focus on sustainability and socioscientific issues, dealing with issues related to citizenship is now seen as an important element of science education. However, in order to make the world a better place, mere understanding about socioscientific issues is not enough. Action must also be taken. In this study, 35 international gifted students-potential scientists-aged 15-19 were interviewed to investigate what they were doing to make the world a better place. The interviews were analyzed using qualitative content analysis with focus on students' actions toward a better world, their rationalizations for such actions, and the role of science in the rationalizations. The analysis shows that students consciously take a wide range of actions, and that they see citizenship as a process of constant self-development. The three categories created to highlight the variation in the ways students take action were personally responsible actions, participatory actions, and preparing for future. Although many students saw that science and scientists play a big role in solving especially the environmental problems, most of them also discussed the structural causes for problems, as well as the interplay of social, economic, and political forces. The results indicate that citizenship science education should take the variety of students' actions into consideration, give students the possibility to take individual and participatory action, as well as give students opportunities to get to know and discuss the ways a career in science or engineering can contribute to saving the world.

Research Opportunities in Solid Earth Science (RESESS): Broadening Participation in Geology and Geophysics (Invited)

NASA Astrophysics Data System (ADS)

Eriksson, S. C.; Hubenthal, M.

2009-12-01

RESESS is a multi-year, paid, summer research internship program designed for students from underrepresented groups. The students receive extensive mentoring in science research and communication and become part of a community that provides ongoing support. This has been possible in the initial 5 years of the program through collaboration with Significant Opportunities in Atmospheric Research and Science (SOARS), where solid earth students have been an integral part of the SOARS cohort, benefiting from social as well as educational interactions. 11 students have taken part in RESESS for at least one year and of these, four students have graduated in geoscience and entered graduate programs in geophysics and one was recently awarded an NSF graduate fellowship. Students have presented over 20 posters at national science meetings, and one has co-authored a peer-reviewed article. 23 scientists have mentored students over the past 5 years and 17 percent of these mentors are from underrepresented groups in science; 19 other scientists and university/science consortia staff have mentored students in written and verbal presentations and supported their integration into the local communities. Mentorship over a period of years is one important hallmark of this program as students have benefited from the support of UNAVCO, IRIS, USGS, and university scientists and staff during the summer, academic year, and at professional meetings such as AGU, GSA, NABGG, and SACNAS as well as consortia and project science workshops (UNAVCO, IRIS, and EarthScope). One goal of the project has been to educate the scientific community on the benefits of mentoring undergraduate students from underrepresented groups in STEM fields. Increasingly, scientists are approaching RESESS to include this program in their implementation of broader impacts. RESESS has been funded by NSF for the next five years with plans to expand the number of students, geographic and scientific diversity, and sources of funding for a sustainable program. Collaboration with the IRIS REU program and major research programs such as POLENET began over the past three years. Synergistic activities will be increased with the inauguration of the IRIS Minority Speakers Series, partnership with the Colorado Diversity Initiative, and expanded recruitment and research opportunities from universities and colleges nation-wide.

Who Am I versus Who Can I Become? Exploring Women's Science Identities in STEM Ph.D. Programs

ERIC Educational Resources Information Center

Szelényi, Katalin; Bresonis, Kate; Mars, Matthew M.

2016-01-01

This article explores the science identities of 21 women STEM Ph.D. students at three research universities in the United States. Following a narrative approach, the findings depict five salient science identities, including those of a) academic, b) entrepreneurial, c) industrial, and d) policy scientist and e) scientist as community educator. Our…

Science Writer-At-Sea: A New InterRidge Education Outreach Project Joining Scientists and Future Journalists

NASA Astrophysics Data System (ADS)

Kusek, K. M.; Freitag, K.; Devey, C.

2005-12-01

The Science Writer-at-Sea program is one small step in a marathon need for improved coverage of science and environmental issues. It targets two significant links in the Earth science communication pipeline: marine scientists and journalists; and attempts to reconnect people with the Earth by boosting their understanding of Earth science and its relevance to society. How it works: Journalism graduate students are invited to participate in oceanographic expeditions affiliated with InterRidge, an international organization dedicated to promoting ocean ridge research. InterRidge's outreach coordinator and science writer prepares each student for the expedition experience using materials she developed based on years of at-sea reporting. The students work side-by-side with the science writer and the scientists to research and write innovative journalistic stories for a general audience that are featured on a uniquely designed multimedia website that includes videos and images. The science, journalism and public communities benefit from this cost-effective program: science research is effectively showcased, scientists benefit from interactions with journalists, science outreach objectives are accomplished; student journalists enjoy a unique hands-on, `boot camp' experience; and the website enhances public understanding of `real' Earth science reported `on scene at sea.' InterRidge completed its first pilot test of the program in August 2005 aboard a Norwegian research cruise. A student writer entering the science journalism program at Columbia University participated. The results exceeded expectations. The team discovered the world's northernmost vent fields on the cruise, which expanded the original scope of the website to include a section specifically designed for the international press. The student was inspired by the cruise, amazed at how much she learned, and said she entered graduate school with much more confidence than she had prior to the program. The site, translated into German, and is being showcased in a museum in Germany. Given the great response from a diverse suite of reviewers, the team is now pursuing long term funding; additional partners in the science, education and journalism communities; and partnerships with marine science and education magazines.

Tools for Engaging Scientists in Education and Public Outreach: Resources from NASA's Science Mission Directorate Forums

NASA Astrophysics Data System (ADS)

Buxner, S.; Grier, J.; Meinke, B. K.; Gross, N. A.; Woroner, M.

2014-12-01

The NASA Science Education and Public Outreach (E/PO) Forums support the NASA Science Mission Directorate (SMD) and its E/PO community by enhancing the coherency and efficiency of SMD-funded E/PO programs. The Forums foster collaboration and partnerships between scientists with content expertise and educators with pedagogy expertise. We will present tools to engage and resources to support scientists' engagement in E/PO efforts. Scientists can get connected to educators and find support materials and links to resources to support their E/PO work through the online SMD E/PO community workspace (http://smdepo.org) The site includes resources for scientists interested in E/PO including one page guides about "How to Get Involved" and "How to Increase Your Impact," as well as the NASA SMD Scientist Speaker's Bureau to connect scientists to audiences across the country. Additionally, there is a set of online clearinghouses that provide ready-made lessons and activities for use by scientists and educators: NASA Wavelength (http://nasawavelength.org/) and EarthSpace (http://www.lpi.usra.edu/earthspace/). The NASA Forums create and partner with organizations to provide resources specifically for undergraduate science instructors including slide sets for Earth and Space Science classes on the current topics in astronomy and planetary science. The Forums also provide professional development opportunities at professional science conferences each year including AGU, LPSC, AAS, and DPS to support higher education faculty who are teaching undergraduate courses. These offerings include best practices in instruction, resources for teaching planetary science and astronomy topics, and other special topics such as working with diverse students and the use of social media in the classroom. We are continually soliciting ways that we can better support scientists' efforts in effectively engaging in E/PO. Please contact Sanlyn Buxner (buxner@psi.edu) or Jennifer Grier (jgrier@psi.edu) to give us feedback on these resources or others you would like to see.

Factual accuracy and the cultural context of science in popular media: Perspectives of media makers, middle school students, and university students on an entertainment television program.

PubMed

Szu, Evan; Osborne, Jonathan; Patterson, Alexis D

2017-07-01

Popular media influences ideas about science constructed by the public. To sway media productions, public policy organizations have increasingly promoted use of science consultants. This study contributes to understanding the connection from science consultants to popular media to public outcomes. A science-based television series was examined for intended messages of the creator and consulting scientist, and received messages among middle school and non-science university students. The results suggest the consulting scientist missed an opportunity to influence the portrayal of the cultural contexts of science and that middle school students may be reading these aspects uncritically-a deficiency educators could potentially address. In contrast, all groups discussed the science content and practices of the show, indicating that scientific facts were salient to both media makers and audiences. This suggests popular media may influence the public knowledge of science, supporting concerns of scientists about the accuracy of fictional television and film.

Communicating Ocean Sciences to Informal Audiences (COSIA): Universities, Oceanographic Institutions, Science Centers and Aquariums Working Together to Improve Ocean Education and Public Outreach

NASA Astrophysics Data System (ADS)

Glenn, S.; McDonnell, J.; Halversen, C.; Zimmerman, T.

2006-12-01

Ocean observatories have already demonstrated their ability to maintain long-term time series, capture episodic events, provide context for improved shipboard sampling, and improve accessibility to a broader range of participants. Communicating Ocean Sciences, an already existing college course (http://www.cacosee.net/collegecourse) from COSEE California has demonstrated its ability to teach future scientists essential communication skills. The NSF-funded Communicating Ocean Sciences to Informal Audiences (COSIA) project will leverage these experiences and others to demonstrate a long-term model for promoting effective science communication skills and techniques applicable to diverse audiences. The COSIA effort will be one of the pathfinders for ensuring that the new scientific results from the increasing U.S. investments in ocean observatories is effectively communicated to the nation, and will serve as a model for other fields. Our presentation will describe a long-term model for promoting effective science communication skills and techniques applicable to diverse audiences. COSIA established partnerships between informal science education institutions and universities nationwide to facilitate quality outreach by scientists and the delivery of rigorous, cutting edge science by informal educators while teaching future scientists (college students) essential communication skills. The COSIA model includes scientist-educator partnerships that develop and deliver a college course derived from COS that teaches communication skills through the understanding of learning theory specifically related to informal learning environments and the practice of these skills at aquariums and science centers. The goals of COSIA are to: provide a model for establishing substantive, long-term partnerships between scientists and informal science education institutions to meet their respective outreach needs; provide future scientists with experiences delivering outreach to informal institutions and promoting the broader impact of research; and provide diverse role models and inquiry-based ocean sciences activities for children and families visiting ISEI. COSIA partners include: Hampton University Virginia Aquarium; Oregon State University Hatfield Marine Science Visitor's Center; Rutgers University Liberty Science Center; University of California, Berkeley Lawrence Hall of Science; and University of Southern California Aquarium of the Pacific. COS has been or will soon be taught at Rutgers University, UC Berkeley, Stanford, Woods Hole Oceanographic Institute, University of Oregon (GK-12 program), Scripps Institution of Oceanography, and others. Data from surveys of students demonstrates improvement in their understanding of how people learn and how to effectively communicate. For example, there was a decrease in agreement with statements describing traditional didactic teaching strategies suggesting that students who took the course developed a more sophisticated, inquiry-based philosophy of learning. Providing college students with a background in current learning theory, and applying that theory through practical science communication experiences, will empower future generations of scientists to meet the communication challenges they will encounter in their careers.

Integrating Research and Education in a Study of Biocomplexity in Arctic Tundra Ecosystems: Costs, Results, and Benefits to the Research Agenda

NASA Astrophysics Data System (ADS)

Gould, W. A.; González, G.; Walker, D. A.

2006-12-01

The integration of research and education is one of the fundamental goals of our national science policy. There is strong interest to improve this integration at the graduate and undergraduate levels, with the general public, and with local and indigenous people. Efforts expended in integrating research and education can occur at the expense of research productivity and represent a cost. Results may include number of personnel involved, activities accomplished, research or other products produced. Benefits are difficult to quantify and may be short term and tangible, e.g. education-research projects enhancing research productivity with publications, or long-term and include intangibles such as personal interactions and experiences influencing career choices, the perception of research activities, enhanced communication, and direct or indirect influence on related research and educational projects. We have integrated the University field course Arctic Field Ecology with an interdisciplinary research project investigating the interactions of climate, vegetation, and permafrost in the study Biocomplexity of Arctic Tundra Ecosystems. The integration is designed to give students background in regional ecology; introduce students to the project objectives, methods, and personnel; provide for interaction with participating scientists; conduct research initiated by the class and instructors; and provide the opportunity to interact with indigenous people with interests in traditional ecological knowledge and land management. Our costs included increased logistical complexity and time-demands on the researchers and staff managing the integration. The educational component increased the size of the research group with the addition of 55 participants over the 4 field seasons of the study. Participants came from 7 countries and included 20 enrolled university students, 18 Inuit non student participants, 9 Inuit students, 3 visiting scientists, 3 staff, and 2 scientist-instructors. The educational component initiated 6 research studies at a series of eight sites along the complete climatic gradient of the North America Arctic. These include studies of variation in nonsorted circle morphology, climatic and cryoturbation effects on species diversity and community composition of plants and soil invertebrates, and an analysis of climatic and cryoturbation effects controls on litter decomposition and soil microbial biomass. A youth-elder-science camp was conducted which introduced Inuit students to permafrost and nonsorted circles. Four students have continued their involvement with the Biocomplexity study as graduate or post graduate students. Indirect benefits are difficult to assess but the integration has allowed a number of students to participate directly with the research team, drawn by the opportunity to gain education and experience over the course of a field season, and this participation has had synergistic benefits with the research agenda of the project.

Engaging Scientists in NASA Education and Public Outreach: K - 12 Formal Education

NASA Astrophysics Data System (ADS)

Bartolone, Lindsay; Smith, D. A.; Eisenhamer, B.; Lawton, B. L.; Universe Professional Development Collaborative, Multiwavelength; NASA Data Collaborative, Use of; SEPOF K-12 Formal Education Working Group; E/PO Community, SMD

2014-01-01

The NASA Science Education and Public Outreach Forums support the NASA Science Mission Directorate (SMD) and its education and public outreach (E/PO) community through a coordinated effort to enhance the coherence and efficiency of SMD-funded E/PO programs. The Forums foster collaboration between scientists with content expertise and educators with pedagogy expertise. We present opportunities for the astronomy community to participate in collaborations supporting the NASA SMD efforts in the K - 12 Formal Education community. Members of the K - 12 Formal Education community include classroom educators, homeschool educators, students, and curriculum developers. The Forums’ efforts for the K - 12 Formal Education community include a literature review, appraisal of educators’ needs, coordination of audience-based NASA resources and opportunities, professional development, and support with the Next Generation Science Standards. Learn how to join in our collaborative efforts to support the K - 12 Formal Education community based upon mutual needs and interests.

A Comprehensive Approach to Partnering Scientists with Education and Outreach Activities at a National Laboratory

NASA Astrophysics Data System (ADS)

Foster, S. Q.

2002-12-01

With the establishment of an Office of Education and Outreach (EO) in 2000 and the adoption of a five-year EO strategic plan in 2001, the University Corporation for Atmospheric Research (UCAR) committed to augment the involvement of AGU scientists and their partners in education and public outreach activities that represent the full spectrum of research in the atmospheric and related sciences. In 2002, a comprehensive program is underway which invites scientists from UCAR, the National Center for Atmospheric Research (NCAR), and UCAR Office of Programs (UOP) into partnership with EO through volunteer orientation workshops, program specific training, skill-building in pedagogy, access to classroom resources, and program and instructor evaluation. Scientists contribute in one or several of the following roles: program partners who bridge research to education through collaborative grant proposals; science content advisors for publications, web sites, exhibits, and informal science events; science mentors for high school and undergraduate students; NCAR Mesa Laboratory tour guides; scientists in the schools; science education ambassadors to local and national community events; science speakers for EO programs, conferences, and meetings of local organization; and science wizards offering demonstrations at public events for children and families. This new EO initiative seeks to match the expertise and specific interests of scientists with appropriate activities, while also serving as a communications conduit through which ideas for new activities and resources can be seeded and eventually developed into viable, fully funded programs.

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.

MS PHD'S: Bridging the Gap of Academic and Career Success Through Educational and Professional Development for Minorities

NASA Astrophysics Data System (ADS)

Brown, D.; Vargas, W.; Padilla, E.; Strickland, J.; Echols, E.; Johnson, A.; Williamson Whitney, V.; Ithier-Guzman, W.; Ricciardi, L.; Johnson, A.; Braxton, L.

2011-12-01

Historically, there has been a lack of ethnic and gender diversity in the geo-sciences. The Minorities Striving and Pursuing Higher Degrees of Success in Earth System Science (MS PHD'S) Professional Development Program provides a bridge to young scientists of diverse backgrounds who in turn will impact many. In a process of 3 phases, the program introduces the students to the scientific community through participation in professional and society meetings and networking with scientists and personnel within federal agencies, academic institutions and STEM-based industries. The program builds confidence, offers role models for professional development and provides students support during their education. Upon completion, students achieve a high level of self-actualization and self-esteem combined with individual growth. They become part of a community that continuously provides support and security to each other. This support is tangible through the mentor/mentee relationships which will help with individual growth throughout the mentoring cycle. Having role models and familiar faces to whom mentees can relate to will encourage our students to succeed in the STEM's field. To date, 159 students have participated in the program: 26 have successfully completed their PhD and 56 are currently enrolled in the PhD programs nationwide. The MS PHD'S Program creates a forum of diverse peoples by diverse peoples with diverse interest and strength, where the ongoing goal is to continually raise the bar for each individual. MS PHD'S establishes a nurturing goal-oriented environment for the geo scientist of the future who in turn will make profound contributions on a local, national and global scale. To conclude, MSPHD'S not only bridges the gap of unrepresented minorities in STEM careers, but also generates educational approaches to make the earth system sciences available to more, impacting all.

Using NMR to Expand Chemistry Research and Educational Experiences at North Carolina Central University, an Historically Black University

DTIC Science & Technology

analytical chemistry . Most students do not get hands-on training with an NMR within their classroom or laboratory courses. The NMR will provide...unique opportunities to our students as they train to become the next generation of scientists, doctors, and engineers .

Learning to Feel Like a Scientist

ERIC Educational Resources Information Center

Jaber, Lama Z.; Hammer, David

2016-01-01

There is increased attention in the science education community on the importance of engaging students in the practices of science. However, there is much to be learned about "how" students enter into and sustain their engagement in these practices. In this paper, we argue that "epistemic affect"--feelings and emotions…

Brains--Computers--Machines: Neural Engineering in Science Classrooms

ERIC Educational Resources Information Center

Chudler, Eric H.; Bergsman, Kristen Clapper

2016-01-01

Neural engineering is an emerging field of high relevance to students, teachers, and the general public. This feature presents online resources that educators and scientists can use to introduce students to neural engineering and to integrate core ideas from the life sciences, physical sciences, social sciences, computer science, and engineering…

Science Books for Professional Pleasure Reading

ERIC Educational Resources Information Center

Smith, Grinell

2008-01-01

In this article, the author presents a list of science books that will foster students' interest in science. Some books were suggested by scientists, science educators, and former students. Some came from an analogous list for science journalists compiled by Boyce Rensberger, director of the Knight Science Journalism Fellowship at MIT. Some are…

The MY NASA DATA Project: Preparing Future Earth and Environmental Scientists, and Future Citizens

NASA Astrophysics Data System (ADS)

Chambers, L. H.; Phelps, C. S.; Phipps, M.; Holzer, M.; Daugherty, P.; Poling, E.; Vanderlaan, S.; Oots, P. C.; Moore, S. W.; Diones, D. D.

2008-12-01

For the past 5 years, the MY NASA DATA (MND) project at NASA Langley has developed and adapted tools and materials aimed at enabling student access to real NASA Earth science satellite data. These include web visualization tools including Google Earth capabilities, but also GPS and graphing calculator exercises, Excel spreadsheet analyses, and more. The project team, NASA scientists, and over 80 classroom science teachers from around the country, have created over 85 lesson plans and science fair project ideas that demonstrate NASA satellite data use in the classroom. With over 150 Earth science parameters to choose from, the MND Live Access Server enables scientific inquiry on numerous interconnected Earth and environmental science topics about the Earth system. Teachers involved in the project report a number of benefits, including networking with other teachers nationwide who emphasize data collection and analysis in the classroom, as well as learning about other NASA resources and programs for educators. They also indicate that the MND website enhances the inquiry process and facilitates the formation of testable questions by students (a task that is typically difficult for students to do). MND makes science come alive for students because it allows them to develop their own questions using the same data scientists use. MND also provides educators with a rich venue for science practice skills, which are often overlooked in traditional curricula as teachers concentrate on state and national standards. A teacher in a disadvantaged school reports that her students are not exposed to many educational experiences outside the classroom. MND allows inner city students to be a part of NASA directly. They are able to use the same information that scientists are using and this gives them inspiration. In all classrooms, the MND microsets move students out of their local area to explore global data and then zoom back into their homes realizing that they are a part of the global Earth System. These armchair explorers learn to unite datasets in a region to learn about places like and unlike where they live. In a world that's becoming smaller and smaller with the aid of technology, projects like MND prepare our students for their global future. A teacher located in an area of California strongly impacted by pollution and potential climate changes noted that this project makes available data that are very relevant to issues that will affect her students' lives. She points out that not all scientific information they currently see is in a form that is understandable to an educated citizen, and that the experience with MND will enable her students to have better than average skills not only for deciphering scientific maps and graphs; but also for creating maps and graphics that successfully convey information to others.

Interfacing microbiology and biotechnology. Conference abstracts

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

Maupin, Julia A.

2001-05-19

The Interfacing Microbiology and Biotechnology Conference was attended by over 100 faculty, post-docs, students, and research scientists from the US, Europe, and Latin America. The conference successfully stimulated communication and the dissemination of knowledge among scientists involved in basic and applied research. The focus of the conference was on microbial physiology and genetics and included sessions on C1 metabolism, archaeal metabolism, proteases and chaperones, gene arrays, and metabolic engineering. The meeting provided the setting for in-depth discussions between scientists who are internationally recognized for their research in these fields. The following objectives were met: (1) The promotion of interaction andmore » future collaborative projects among scientists involved in basic and applied research which incorporates microbial physiology, genetics, and biochemistry; (2) the facilitation of communication of new research findings through seminars, posters, and abstracts; (3 ) the stimulation of enthusiasm and education among participants including graduate and undergraduate students.« less

What will it take? Pathways, time and funding: Australian medical students' perspective on clinician-scientist training.

PubMed

Eley, Diann S; Jensen, Charmaine; Thomas, Ranjeny; Benham, Helen

2017-12-08

Clinician-scientists are in decline worldwide. They represent a unique niche in medicine by bridging the gap between scientific discovery and patient care. A national, integrated approach to training clinician-scientists, typically programs that comprise a comprehensive MD-PhD pathway, are customary. Such a pathway is lacking in Australia. The objective was to gather perceptions from Australian medical students on factors they perceive would influence their decision to pursue clinician-scientist training. A cross-sectional mixed methods design used quantitative and qualitative questions in an online self-report survey with medical students from a four-year MD program. Quantitative measures comprised scaled response questions regarding prior experience and current involvement in research, and short- and long-term opinions about factors that influence their decisions to undertake a research higher degree (RHD) during medical school. Qualitative questions gathered broader perceptions of what a career pathway as a clinician-scientist would include and what factors are most conducive to a medical student's commitment to MD-PhD training. Respondents (N = 418; 51% female) indicated Time, Funding and Pathway as the major themes arising from the qualitative data, highlighting negative perceptions rather than possible benefits to RHD training. The lack of an evident Pathway was inter-related to Time and Funding. Themes were supported by the quantitative data. Sixty percent of students have previous research experience of varying forms, and 90% report a current interest, mainly to improve their career prospects. The data emphasise the need for an MD-PhD pathway in Australia. A model that provides an early, integrated, and exclusive approach to research training pathways across all stages of medical education is suggested as the best way to rejuvenate the clinician-scientist. A national pathway that addresses factors influencing career decision making throughout the medical education continuum should include an appropriate funding structure, and provide early and continuing advice and mentoring. It should be flexible, gender equitable, and include post-graduate training. The implications of implementing MD-PhD programs represent a substantial investment. However this should not be a deterrent to Australia's commitment to an MD-PhD pathway, but rather a challenge to help ensure our future healthcare is guided by highly trained and competent clinician-scientists.

GGD NSU: Tips to Teach Students as Young Scientists

NASA Astrophysics Data System (ADS)

Rakhmenkulova, I. F.; Zhitova, L.

2013-12-01

Novosibirsk State University (NSU) is different from other universities in Russia. The campus is located in Academgorodok, a unique place where more than 30 scientific institutes and Academpark (Technopark) are located. The students are involved in scientific research from the third year of their study (some try to work part-time in scientific institutions even from their first year). All the university professors are highly-qualified scientists working full-time in scientific institutions. Geology and Geophysics Department (GGD) of NSU is currently reforming the education system and policy. The reform involves the following steps: 1. New scientific programs and courses on modern science have been introduced; the priority should be given to courses in English, as the international language. 2. A special annual conference for students and young scientists was organized in August 2013 in Shira (a place where GGD students have their field trips). 3. International scientists are invited to give seminars and teach on a regular basis. 4. International students are welcomed to study at GGD NSU. 5. GGD stuff is creating a new scientific laboratory within the university. All the above-mentioned steps should ';launch' GGD NSU into a new ';orbit': improve the study process and help the university to be integrated into the world's community.

Reading, Writing, and Rings!

ERIC Educational Resources Information Center

Aschbacher, Pamela; Li, Erika; Hammon, Art

2008-01-01

"Reading, Writing, and Rings!" was created by a team of elementary teachers, literacy experts, and scientists in order to integrate science and literacy. These free units bring students inside NASA's Cassini-Huygens mission to Saturn. The authors--a science teacher and education outreach specialist and two evaluators of educational programs--have…

Engaging Pennsylvania Teachers in Watershed Education

ERIC Educational Resources Information Center

Gruver, Joshua; Luloff, A. E.

2008-01-01

Water-resource scientists have become increasingly concerned about global water quality and quantity issues. Water and watershed education are now mandated topics for school-aged youth. Pennsylvania teachers lack consistent and accessible curricula to teach students about water quality and quantity. A mail survey administered in 2004 determined…

Building Interdisciplinary Research and Communication Skills in the Agricultural and Climate Sciences

NASA Astrophysics Data System (ADS)

Johnson-Maynard, J.; Borrelli, K.; Wolf, K.; Bernacchi, L.; Eigenbrode, S.; Daley Laursen, D.

2015-12-01

Preparing scientists and educators to create and promote practical science-based agricultural approaches to climate change adaptation and mitigation is a main focus of the Regional Approaches to Climate Change (REACCH) project. Social, political and environmental complexities and interactions require that future scientists work across disciplines rather than having isolated knowledge of one specific subject area. Additionally, it is important for graduate students earning M.S. or Ph.D. degrees in agriculture and climate sciences to be able to communicate scientific findings effectively to non-scientific audiences. Unfortunately, university graduate curricula rarely adequately prepare students with these important skills. REACCH recognizes the need for graduate students to have thorough exposure to other disciplines and to be able to communicate information for outreach and education purposes. These priorities have been incorporated into graduate training within the REACCH project. The interdisciplinary nature of the project and its sophisticated digital infrastructure provide graduate students multiple opportunities to gain these experiences. The project includes over 30 graduate students from 20 different disciplines and research foci including agronomy, biogeochemistry, soil quality, conservation tillage, hydrology, pest and beneficial organisms, economics, modeling, remote sensing, science education and climate science. Professional develop workshops were developed and held during annual project meetings to enhance student training. The "Toolbox" survey (http://www.cals.uidaho.edu/toolbox/) was used to achieve effective interdisciplinary communication. Interdisciplinary extension and education projects were required to allow students to gain experience with collaboration and working with stakeholder groups. Results of student surveys and rubrics developed to gauge success in interdisciplinary research and communication may provide a helpful starting point for future projects involving graduate student training.

Summer of Innovation Kick Off

NASA Image and Video Library

2010-06-09

Jet Propulsion Laboratory Manager of Elementary and Secondary Education David Seidel motivates teachers and middle school students during the kick off of NASA's Summer of Innovation program at the Jet Propulsion Laboratory in Pasadena, Calif., Thursday, June 10, 2010. Through the program, NASA will engage thousands of middle school students and teachers in stimulating math and science-based education programs with the goal of increasing the number of future scientists, mathematicians, and engineers. Photo Credit: (NASA/Bill Ingalls)

Exploring the Solar System Activities Outline: Hands-On Planetary Science for Formal Education K-14 and Informal Settings

NASA Technical Reports Server (NTRS)

Allen, J. S.; Tobola, K. W.; Lindstrom, M. L.

2003-01-01

Activities by NASA scientists and teachers focus on integrating Planetary Science activities with existing Earth science, math, and language arts curriculum. The wealth of activities that highlight missions and research pertaining to the exploring the solar system allows educators to choose activities that fit a particular concept or theme within their curriculum. Most of the activities use simple, inexpensive techniques that help students understand the how and why of what scientists are learning about comets, asteroids, meteorites, moons and planets. With these NASA developed activities students experience recent mission information about our solar system such as Mars geology and the search for life using Mars meteorites and robotic data. The Johnson Space Center ARES Education team has compiled a variety of NASA solar system activities to produce an annotated thematic outline useful to classroom educators and informal educators as they teach space science. An important aspect of the outline annotation is that it highlights appropriate science content information and key science and math concepts so educators can easily identify activities that will enhance curriculum development. The outline contains URLs for the activities and NASA educator guides as well as links to NASA mission science and technology. In the informal setting educators can use solar system exploration activities to reinforce learning in association with thematic displays, planetarium programs, youth group gatherings, or community events. Within formal education at the primary level some of the activities are appropriately designed to excite interest and arouse curiosity. Middle school educators will find activities that enhance thematic science and encourage students to think about the scientific process of investigation. Some of the activities offered are appropriate for the upper levels of high school and early college in that they require students to use and analyze data.

ESL through Content-Area Instruction. Language in Education: Theory and Practice 69.

ERIC Educational Resources Information Center

Crandall, JoAnn, Ed.

The concept of integrating language instruction with subject matter instruction is not new to language educators. It has been attempted for many years in adult education, in university programs for foreign students, and in specialized language courses for scientists, businessmen, and other professionals. To some degree, it has also been a part of…

Planting local seed for growth to nationwide E/PO efforts

NASA Astrophysics Data System (ADS)

Fox, N.; Beisser, K.; Mendez, F.; Cockrell, D.; Wilhide, B.

The Johns Hopkins University Applied Physics Laboratory (JHU/APL) is the home to hundreds of scientists and engineers, all involved in research, design and implementation of space missions. Many of these people actively seek out ways to raise awareness and interest in the local community by visiting schools, giving public lectures and supporting events held at the laboratory. During the past few years, APL has begun to foster a number of firm partnerships with organizations to further these community opportunities and provide a test bed for both formal and informal education activities through the Space Department E/PO office One of our ongoing partnerships is with the Maryland Science Center in Baltimore. A continual challenge faced by museums is how to stay current and allow visitors to experience the immediacy and excitement of scientific discovery. To help meet these challenges, the Maryland Science Center houses "SpaceLink", the Nation's first space, science and astronomy update center. Part media center, part discovery room, and part newsroom, the exhibit is a multi-purpose Professional Development Site for educators and a "classroom of the future" for K 12 students. APL scientists and- engineers regularly support SpaceLink's flexible programming, including scientist in residence, monthly credited seminars for educators (Teachers' Thursdays), a menu of Classroom Programs on request, Distance Learning Teacher Presentations, and special Live Events to highlight mission milestones and space-related anniversaries. This allows the guest scientists and engineers to interact directly with the public. These events also compliment the APL exhibits housed at the Science Center. JHU/APL offers an exciting environment for the study of applications in space by hosting the annual Maryland Summer Center for Space Science sponsored by the Maryland State Department of Education. Rising 6t h and 7t h grade students learn to harness the power of technology and keep pace with the expanding knowledge of space science. They experience the process involved in planning/launching a simulated space mission, including design/fabrication of instrumentation for a spacecraft. They are part of a Mission Team that built a spacecraft scale model complete with instrumentation and even give a full mission overview oral presentation to their peers. During this 2 week experience, the students interact with the APL scientists and engineers directly responsible for the featured missions. Scientists and engineers team up with Comcast Cablevision of Maryland, Cable in the Classroom, and the Maryland State Department of Education to give Maryland middle school students a true outer space experience focusing on specific NASA missions. The students move from behind their desks to behind the scenes of a deep- space mission at JHU/APL. The students hear mission briefings and take part in a special student press conference with mission team members. They don clean-room suits and tour the Lab's space facilities, including the Mission Operations Center, the space environment simulation lab, the vibration test lab, and the satellite communications facility. These local programs for outreach opportunities have often served as the test bed for national programs and partnerships. In this presentation we will review the local programs to show how the organizations benefit from the partnership with APL and also how the APL outreach programs gain a much wider and more appreciative audience. We will also show how these programs are being expanded to a more nationwide focus.

Students' ideas about prismatic images: teaching experiments for an image-based approach

NASA Astrophysics Data System (ADS)

Grusche, Sascha

2017-05-01

Prismatic refraction is a classic topic in science education. To investigate how undergraduate students think about prismatic dispersion, and to see how they change their thinking when observing dispersed images, five teaching experiments were done and analysed according to the Model of Educational Reconstruction. For projection through a prism, the students used a 'split image projection' conceptualisation. For the view through a prism, this conceptualisation was not fruitful. Based on the observed images, six of seven students changed to a 'diverted image projection' conceptualisation. From a comparison between students' and scientists' ideas, teaching implications are derived for an image-based approach.

Have Astronauts Visited Neptune? Student Ideas about How Scientists Study the Solar System

ERIC Educational Resources Information Center

Palma, Christopher; Plummer, Julia; Rubin, KeriAnn; Flarend, Alice; Ong, Yann Shiou; McDonald, Scott; Ghent, Chrysta; Gleason, Timothy; Furman, Tanya

2017-01-01

The nature of students' ideas about the scientific practices used by astronomers when studying objects in our Solar System is of widespread interest to discipline-based astronomy education researchers. A sample of middle-school, high-school, and college students (N = 42) in the U.S. were interviewed about how astronomers were able to learn about…

Impact of Project-Based Curriculum Materials on Student Learning in Science: Results of a Randomized Controlled Trial

ERIC Educational Resources Information Center

Harris, Christopher J.; Penuel, William R.; D'Angelo, Cynthia M.; DeBarger, Angela Haydel; Gallagher, Lawrence P.; Kennedy, Cathleen A.; Cheng, Britte Haugen; Krajcik, Joseph S.

2015-01-01

The "Framework for K-12 Science Education" (National Research Council, 2012) sets an ambitious vision for science learning by emphasizing that for students to achieve proficiency in science they will need to participate in the authentic practices of scientists. To realize this vision, all students will need opportunities to learn from…

Discerning Selective Traditions in Science Education: A Qualitative Study of Teachers' Responses to What Is Important in Science Teaching

ERIC Educational Resources Information Center

Sund, Per

2016-01-01

Science teachers have differing views about what students should learn. Their teaching experience often leads them to develop habitual answers to students' questions, such as--why should I learn this? Some teachers argue that students need to learn more "canonical" science knowledge so that they can become scientists, while others tell…

From a Sense of Stereotypically Foreign to Belonging in a Science Community: Ways of Experiential Descriptions About High School Students' Science Internship

NASA Astrophysics Data System (ADS)

Hsu, Pei-Ling; Roth, Wolff-Michael

2010-05-01

Science educators often suggest that students should learn science in ways and settings that bear family resemblance with “the real thing.” Internship in science laboratories constitutes one such way in which students may learn science and learn about science. However, very little is known about how participants experience a science internship in an “authentic” science setting (i.e., a science laboratory). Our study was designed to understand the nature of participants’ experiences of “authentic science.” Participants included 11 high school students, one high school teacher, five laboratory technicians, and two scientists. High school students practiced science alongside technicians (young scientists) in real ongoing projects of a biology laboratory. Data sources include 19 semi-structured and video-recorded interviews held after the 2-month science internship. Drawing on phenomenographic method, we identified five categories of experiential descriptions: (a) authenticity of university science, (b) channeling and connecting different communities, (c) advanced knowledge required in and lengthy procedures mobilized by university science, (d) self-exploration and reflection, and (e) comprehensive science learning. Each category’s meaning for participants and implications for science education are illustrated and discussed. This study demonstrates positive evidence of the science internship on helping students learn different dimensions of science and reflect their relationship with science. Suggestions on facilitating the partnership between secondary and postsecondary education are provided.

Making Real Life Connections and Engaging High School Students as They Become Climate Detectives using data obtained through JOIDES Resolution Expedition 341

NASA Astrophysics Data System (ADS)

Chegwidden, D.; Mote, A. S.; Manley, J.; Ledley, T. S.; Haddad, N.; Ellins, K.; Lynds, S. E.

2016-02-01

Texas is a state that values and supports an Earth Science curriculum, and as an experienced educator in Texas, I find it crucial to educate my students about the various Ocean Science careers that exist and also be able to use the valuable data that is obtained in a core sample from the ocean floor. "Climate Detective" is an EarthLabs module that is supported by TERC and International Ocean Discovery Program (IODP) Expedition 341. This module contains hands-on activities, many opportunities to interpret actual data from a core sample, and collaborative team skills to solve a problem. Through the module, students are able to make real connections with scientists when they understand various roles aboard the JOIDES Resolution. Students can also visually experience real-time research via live video streaming within the research vessel. In my classroom, the use of the "Climate Detective" not only establishes a beneficial relationship between teacher and marine scientists, but such access to the data also helps enhance the climate-related concepts and explanatory procedures involved in obtaining reports. Data is applied to a challenge question for all student groups to answer at the end of the module. This Project-based learning module emphasizes different forms of evidence and requires that learners apply different inquiry approaches to build the knowledge each one needs to acquire, as they become climate-literate citizens. My involvement with the EarthLabs project has strengthened my overall knowledge and confidence to teach about Earth's systems and climate change. In addition, this experience has led me to become an advocate who promotes vigorous classroom discussion among my students; additionally, I am encouraged to collaborate with other educators through the delivery of professional development across the state of Texas. Regularly, I connect with scientists in my classroom and such connection truly enriches not only my personal knowledge, but also provides a foundational understanding for my students.

Integrative Curriculum Development in Nuclear Education and Research Vertical Enhancement Program

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

Egarievwe, Stephen U.; Jow, Julius O.; Edwards, Matthew E.

Using a vertical education enhancement model, a Nuclear Education and Research Vertical Enhancement (NERVE) program was developed. The NERVE program is aimed at developing nuclear engineering education and research to 1) enhance skilled workforce development in disciplines relevant to nuclear power, national security and medical physics, and 2) increase the number of students and faculty from underrepresented groups (women and minorities) in fields related to the nuclear industry. The program uses multi-track training activities that vertically cut across the several education domains: undergraduate degree programs, graduate schools, and post-doctoral training. In this paper, we present the results of an integrativemore » curriculum development in the NERVE program. The curriculum development began with nuclear content infusion into existing science, engineering and technology courses. The second step involved the development of nuclear engineering courses: 1) Introduction to Nuclear Engineering, 2) Nuclear Engineering I, and 2) Nuclear Engineering II. The third step is the establishment of nuclear engineering concentrations in two engineering degree programs: 1) electrical engineering, and 2) mechanical engineering. A major outcome of the NERVE program is a collaborative infrastructure that uses laboratory work, internships at nuclear facilities, on-campus research, and mentoring in collaboration with industry and government partners to provide hands-on training for students. The major activities of the research and education collaborations include: - One-week spring training workshop at Brookhaven National Laboratory: The one-week training and workshop is used to enhance research collaborations and train faculty and students on user facilities/equipment at Brookhaven National Laboratory, and for summer research internships. Participants included students, faculty members at Alabama A and M University and research collaborators at BNL. The activities include 1) tour and introduction to user facilities/equipment at BNL that are used for research in room-temperature semiconductor nuclear detectors, 2) presentations on advances on this project and on wide band-gap semiconductor nuclear detectors in general, and 3) graduate students' research presentations. - Invited speakers and lectures: This brings collaborating research scientist from BNL to give talks and lectures on topics directly related to the project. Attendance includes faculty members, researchers and students throughout the university. - Faculty-students team summer research at BNL: This DOE and National Science Foundation (NSF) program help train students and faculty members in research. Faculty members go on to establish research collaborations with scientists at BNL, develop and submit research proposals to funding agencies, transform research experience at BNL to establish and enhance reach capabilities at home institution, and integrate their research into teaching through class projects and hands-on training for students. The students go on to participate in research work at BNL and at home institution, co-author research papers for conferences and technical journals, and transform their experiences into developing senior and capstone projects. - Grant proposal development: Faculty members in the NERVE program collaborate with BNL scientists to develop proposals, which often help to get external funding needed to expand and sustain the continuity of research activities and supports for student's wages and scholarships (stipends, tuition and fees). - Faculty development and mentoring: The above collaboration activities help faculty professional development. The experiences, grants, joint publications in technical journals, and supervision of student's research, including thesis and dissertation research projects, contribute greatly to faculty development. Senior scientists at BNL and senior faculty members on campus jointly mentor junior faculty members to enhance their professional growth. - Graduate thesis and dissertation research: Brookhaven National Laboratory provides unique opportunities and outstanding research resources for the NERVE program graduate research. Scientists from BNL serve in master's degree thesis and PhD dissertation committees, where they play active roles in the supervision of the research. (authors)« less

Eliminating the OUCH in OUtreaCH

NASA Astrophysics Data System (ADS)

Karsten, J. L.; Manduca, C. A.

2004-12-01

``I'm a scientist who knows how to conduct research, not an expert in teaching pre-college students!'' is a common complaint within the scientific community in response to recent funding agency mandates that research proposals explicitly address education, public outreach or other broader impacts. Yet, these new requirements address several important goals - fostering public support for research funding in the Earth and Space sciences, recruiting the next generation of talented geoscientists in the face of declining student enrollments, and educating the citizenry for informed decision making and advocacy, chief among them. Further, the phrase ``broader impacts'' is not meant to be synonymous with outreach to pre-college students and teachers - agency program managers actually encourage many different types of activity for meeting these obligations. AGU and its Committee on Education and Human Resources (CEHR) are committed to offering an array of programs that facilitate our members' ability to meet these new education, outreach, and broader impacts criteria in support of the research enterprise. CEHR has an on-going need for scientists willing to speak about their research in Geophysical Information for Teacher (GIFT) Workshops, sponsored lectures at annual and regional conventions of the National Science Teachers Association, special symposia for minority high school students attending annual AGU meetings, and career planning workshops for students and early career investigators. More extensive involvement as meeting mentors for minority undergraduate and graduate students is available through AGU's partnership with the new MSPHDS initiative (A. Pyrtle, P.I.). A new AGU outreach web site now under development will make available scientist biographies and abstracts derived from recent scientific articles originally published in AGU journals, which have been rewritten for a public audience. This resource is expected to serve as an important vehicle for AGU members looking to broadly disseminate their research results to the general public, students and teachers, but its success will require significant volunteer contributions in building and maintaining the quality of the collection. As volunteers for CEHR's activities and programs, AGU members can fulfill their broader impacts obligations without the sting of straying too far from their main mission of conducting scientific research. This is a win-win situation for all.

An Internship Model for Culturally Relevant Success for Native American High School Students

NASA Astrophysics Data System (ADS)

Nall, J.; Graham, E. M.

2004-12-01

Culturally relevant educational practices can be challenging to implement in the workplace. In an effort to support equity in access to undergraduate internship opportunities for Native American students, NASA Jet Propulsion Laboratory's (JPL) Education Office, Minority Education Initiatives offers a unique approach to supporting students from Native American reservation high schools in Washington State to participate in eight-week technical (Science, Technology, Engineering and Mathematics related) summer internships. This talk will address the Alliance for Learning and Vision for Americans (ALVA) program's twelve years of success based on four programmatic principals, annual review and the critical support of scientists and engineers.

KSC-2011-3365

NASA Image and Video Library

2011-05-06

Cape Canaveral, Fla. -- Students from across the nation gathered at NASA's Kennedy Space Center in Florida for the NASA Explorer Schools (NES) symposium In the Center for Space Education at Kennedy, a student participates in a hands-on activity as education specialists assist. During the NES event, students presented their investigation project to their peers, scientists, engineers and education specialists. About 60 fourth- through 12-grade students nationwide are at the center May 4-7 participating in tours of processing and launch facilities and the U.S. Astronaut Hall of Fame, as well as several educational activities and a career panel question-and-answer session. About 30 teachers will receive professional development opportunities during the symposium. The participants were competitively selected after they completed an original investigation focused on existing NASA missions or research interests. Photo Credit: NASA/Kim Shiflett

SEAS: Student Experiments At Sea - An Education Outreach Pilot Program Sponsored by the Ridge2000 Program

NASA Astrophysics Data System (ADS)

Goehring, L.

2004-12-01

SEAS is a pilot program for middle and high school students who want to learn science by doing science. SEAS students study the deep sea hydrothermal vent environment and learn to ask questions about this exciting, relatively unexplored world, just as researchers do. SEAS students also learn how to answer their own questions through the process of scientific investigation. With the SEAS program, students have the opportunity to participate in the actual discovery process, along side deep-sea researchers. SEAS builds upon the successes of programs like Dive&Discover and Extreme2000, which demonstrated the capability deep-sea scientists have in engaging students with live research. SEAS extends this concept by inviting students to participate in deep-sea research through formal proposal and report competitions. SEAS challenges students to higher levels of achievement. A curriculum, developed by teachers expert in the translation of scientific inquiry in the classroom, prepares students to participate. SEAS was concept-tested during the 2003-2004 school year, with 14 pilot teachers and approximately 800 students. Twenty Ridge2000 scientists contributed their time and expertise to the SEAS program in its first year. Five student proposals were selected and conducted at sea in April during a Ridge2000 research cruise to the East Pacific Rise. All results were posted to the SEAS website (http://www.ridge2000.org/SEAS/) during the cruise, and students were invited to analyze data for their final reports. Final student reports, along with scientists comments were also posted. During the 2004-2005 school year, SEAS will be evaluated for its impact on student learning and attitudes toward science. The benefits of SEAS to the Ridge2000 scientific community are many. Scientists are invited to contribute in a variety of ways, all of which help satisfy the requirement of NSFs Broader Impacts Criterion. They may contribute time and expertise by answering student questions and reviewing student proposals and reports. They may choose to host the student research on their cruise. By sharing the load, no one scientist is burdened, nor expected to contribute additional funding. The Ridge2000 Program oversees the development, execution and dissemination of SEAS, helping make outreach efficient and easy for scientists.

Neuroscientists' classroom visits positively impact student attitudes.

PubMed

Fitzakerley, Janet L; Michlin, Michael L; Paton, John; Dubinsky, Janet M

2013-01-01

The primary recommendation of the 2010 President's Council of Advisors on Science and Technology report on K-12 education was to inspire more students so that they are motivated to study science. Scientists' visits to classrooms are intended to inspire learners and increase their interest in science, but verifications of this impact are largely qualitative. Our primary goal was to evaluate the impact of a longstanding Brain Awareness classroom visit program focused on increasing learners understanding of their own brains. Educational psychologists have established that neuroscience training sessions can improve academic performance and shift attitudes of students from a fixed mindset to a growth mindset. Our secondary goal was to determine whether short interactive Brain Awareness scientist-in-the-classroom sessions could similarly alter learners' perceptions of their own potential to learn. Teacher and student surveys were administered in 4(th)-6(th) grade classrooms throughout Minnesota either before or after one-hour Brain Awareness sessions that engaged students in activities related to brain function. Teachers rated the Brain Awareness program as very valuable and said that the visits stimulated students' interest in the brain and in science. Student surveys probed general attitudes towards science and their knowledge of neuroscience concepts (particularly the ability of the brain to change). Significant favorable improvements were found on 10 of 18 survey statements. Factor analyses of 4805 responses demonstrated that Brain Awareness presentations increased positive attitudes toward science and improved agreement with statements related to growth mindset. Overall effect sizes were small, consistent with the short length of the presentations. Thus, the impact of Brain Awareness presentations was positive and proportional to the efforts expended, demonstrating that short, scientist-in-the-classroom visits can make a positive contribution to primary school students' attitudes toward science and learning.

Boreal Forest Watch: A BOREAS Outreach Program

NASA Technical Reports Server (NTRS)

Rock, Barrett N.

1999-01-01

The Boreal Forest Watch program was initiated in the fall of 1994 to act as an educational outreach program for the BOREAS project in both the BOREAS Southern Study Area (SSA) and Northern Study Area (NSA). Boreal Forest Watch (13FW) was designed to introduce area high school teachers and their students to the types of research activities occurring as part of the BOREAS study of Canadian boreal forests. Several teacher training workshops were offered to teachers from central and northern Saskatchewan and northern Manitoba between May, 1995 and February, 1999; teachers were introduced to techniques for involving their students in on-going environmental monitoring studies within local forested stands. Boreal Forest Watch is an educational outreach program which brings high school students and research scientists together to study the forest and foster a sustainable relationship between people and the planetary life-support system we depend upon. Personnel from the University of New Hampshire (UNH), Complex Systems Research Center (CSRC), with the cooperation from the Prince Albert National Park (PANP), instituted this program to help teachers within the BOREAS Study Areas offer real science research experience to their students. The program has the potential to complement large research projects, such as BOREAS, by providing useful student- collected data to scientists. Yet, the primary goal of BFW is to allow teachers and students to experience a hands-on, inquiry-based approach to leaming science - emulating the process followed by research scientists. In addition to introducing these teachers to on-going BOREAS research, the other goals of the BFW program were to: 1) to introduce authentic science topics and methods to students and teachers through hands-on, field-based activities; and, 2) to build a database of student-collected environmental monitoring data for future global change studies in the boreal region.

The scientist's education and a civic conscience.

PubMed

Donald, Kelling J; Kovac, Jeffrey

2013-09-01

A civic science curriculum is advocated. We discuss practical mechanisms for (and highlight the possible benefits of) addressing the relationship between scientific knowledge and civic responsibility coextensively with rigorous scientific content. As a strategy, we suggest an in-course treatment of well known (and relevant) historical and contemporary controversies among scientists over science policy or the use of sciences. The scientific content of the course is used to understand the controversy and to inform the debate while allowing students to see the role of scientists in shaping public perceptions of science and the value of scientific inquiry, discoveries and technology in society. The examples of the activism of Linus Pauling, Alfred Nobel and Joseph Rotblat as scientists and engaged citizens are cited. We discuss the role of science professors in informing the social conscience of students and consider ways in which a treatment of the function of science in society may find, coherently, a meaningful space in a science curriculum at the college level. Strategies for helping students to recognize early the crucial contributions that science can make in informing public policy and global governance are discussed.

Providing Context for Complexity: Using Infographics and Conceptual Models to Teach Global Change Processes

NASA Astrophysics Data System (ADS)

Bean, J. R.; White, L. D.

2015-12-01

Understanding modern and historical global changes requires interdisciplinary knowledge of the physical and life sciences. The Understanding Global Change website from the UC Museum of Paleontology will use a focal infographic that unifies diverse content often taught in separate K-12 science units. This visualization tool provides scientists with a structure for presenting research within the broad context of global change, and supports educators with a framework for teaching and assessing student understanding of complex global change processes. This new approach to teaching the science of global change is currently being piloted and refined based on feedback from educators and scientists in anticipation of a 2016 website launch. Global change concepts are categorized within the infographic as causes of global change (e.g., burning of fossil fuels, volcanism), ongoing Earth system processes (e.g., ocean circulation, the greenhouse effect), and the changes scientists measure in Earth's physical and biological systems (e.g., temperature, extinctions/radiations). The infographic will appear on all website content pages and provides a template for the creation of flowcharts, which are conceptual models that allow teachers and students to visualize the interdependencies and feedbacks among processes in the atmosphere, hydrosphere, biosphere, and geosphere. The development of this resource is timely given that the newly adopted Next Generation Science Standards emphasize cross-cutting concepts, including model building, and Earth system science. Flowchart activities will be available on the website to scaffold inquiry-based lessons, determine student preconceptions, and assess student content knowledge. The infographic has already served as a learning and evaluation tool during professional development workshops at UC Berkeley, Stanford University, and the Smithsonian National Museum of Natural History. At these workshops, scientists and educators used the infographic to highlight how their research and activities reinforce conceptual links among global change topics. Pre- and post-workshop assessment results and responses to questionnaires have guided the refinement of classroom activities and assessment tools utilizing flowcharts as models for global change processes.

Plate Boundary Observatory Infrastructure and Data Products in Education and Outreach

NASA Astrophysics Data System (ADS)

Eriksson, S. C.; Barbour, K.; Lee, E.

2005-12-01

As one of three major components of NSF's EarthScope program, the Plate Boundary Observatory (PBO) encourages the integration of research and education. Informing various communities about the current work of PBO and the scientific discoveries related to the use of this instrumentation has contributed to the success of PBO during the first two years of the EarthScope project. UNAVCO(PBO), IRIS (USArray), and the EarthScope project office work together to integrate Education and Outreach (E&O) opportunities into a program that is greater than the sum of its parts and yet maintains the identity of each organization. Building and maintaining the PBO website, documenting and archiving activities of PBO, providing short courses for professional development of scientists using EarthScope data, and developing higher level data products with an appropriate educational framework are a few of the activities that provide both challenges and opportunities. The internet, particularly the World Wide Web, has become the primary tool for disseminating information to various audiences. The primary goals of the PBO website are to provide current information on the progress of GPS and Strainmeter facility construction; to provide access to different levels of data products; and to facilitate networking with and among scientists. Challenges for the PBO website include publishing current stories on installation projects while coordinating with field engineers on a regular basis; providing near to real time updates and maintaining quality assurance processes; and defining personnel requirements for a maintaining a dynamic website. Currently, archived photographs, web diaries, and numerous web highlights document PBO's success and provide a visual record of PBO's accomplishments and behind-the-scene activities over the last two years. The community charged PBO with increasing the number of scientists using its data. UNAVCO does this by providing short courses for professional development of young scientists and more established scientists broadening their research interests. In addition, collecting, manipulating, and aggregating real scientific data for classroom use is a current priority in science education. Educators want their students to use these data to draw conclusions following the logical processes characteristic of the scientific endeavor. Hence, PBO is a natural source of data for use in the classroom. Staff and community members are designing higher level data products for a variety of audiences in formal education (students and instructors in middle/high school, community colleges, undergraduate science majors and students in general science education, graduate students) and in informal education (museums, park information centers, science centers, and media. PBO is working on a chapter for the Earth Exploration Toolbox (http://serc.carleton.edu/eet/) for undergraduate general science education, and the Jules Verne Voyager will include a user-friendly interface and associated educational materials. Evaluation of the effectiveness of this entire program and of individual projects and products is a major undertaking. The multitude of tasks, integration of these tasks into a coherent program, and identification of resources for evaluation are both opportunities and challenges in helping build a program with measurable impact.

Engaging Scientists in NASA Education and Public Outreach: Higher Education

NASA Astrophysics Data System (ADS)

Meinke, Bonnie K.; Smith, D. A.; Schultz, G. R.; Lawton, B. L.; Bianchi, L.; Blair, W. P.; Buxner, S.; SEPOF Higher Education Working Group; E/PO Community, SMD

2014-01-01

The NASA Science Education and Public Outreach Forums support the NASA Science Mission Directorate (SMD) and its education and public outreach (E/PO) community through a coordinated effort to enhance the coherence and efficiency of SMD-funded E/PO programs. The Forums foster collaboration between scientists with content expertise and educators with pedagogy expertise. We present opportunities for the astronomy community to participate in collaborations supporting the NASA SMD efforts in the Higher Education community. Members of the Higher Education community include instructors, faculty, and students at community colleges and four-year colleges/universities. The Forums’ efforts for the Higher Education community include a literature review, appraisal of instructors’ needs, coordination of audience-based NASA resources and opportunities, and classroom support materials. Learn how to join in our collaborative efforts to support the Higher Education community based upon mutual needs and interests.

Emerging Leader for Education and Outreach

NASA Astrophysics Data System (ADS)

Bartholow, S.

2013-12-01

Polar Educators International (PEI) is a global professional network for those who educate in, for, and about the polar regions. Our goal is to connect educators, scientists, and community members to share expertise around the world and to rekindle student and public engagement with global environmental change. The growing membership in over 30 countries is now recognized as a leading organization capable of fulfilling E&O goals of international science organizations and training educators to facilitate outstanding polar science and climate change education in classrooms. This session will address the importance of dedicated, high-caliber, interpersonal professional networks that are linked directly to the expert science community to better serve science goals and education in classrooms. Discover that the educators and scientists in the network are resources themselves to help you become a leader in polar and climate education; arguably our most important content at the international level.

Unraveling the Geologic History of Antarctica Through the Study of Sediment and Rock Cores: The ANDRILL Education and Public Outreach Experience.

NASA Astrophysics Data System (ADS)

Rack, F. R.; Huffman, L.; Berg, M.; Levy, R.; Harwood, D.; Lacy, L.

2007-12-01

ANDRILL (ANtarctic geological DRILLing) is a multinational collaboration involving more than 250 scientists from Germany, Italy, New Zealand and the United States. The ANDRILL Program has mobilized scientists, technicians, drillers, engineers, students and educators from four member nations to bring world-class science into focus and provide in-depth immersive experiences to educators through the ARISE (ANDRILL Research Immersion for Science Educators) Program and Project Iceberg. During two seasons of scientific drilling, encompassing the McMurdo Ice Shelf (MIS) Project and the Southern McMurdo Sound (SMS) Project, 15 educators have been immersed in ANDRILL science and have participated in both learning and teaching experiences. Blogs, video journals, images and other resources were generated and distributed online to teachers, students and the general public through the ANDRILL website as part of Project Iceberg, which was used as a unifying theme for the outreach effort. The video journals chronicled the journey from Lincoln, Nebraska to Antarctica and introduced viewers to many aspects of the ANDRILL program in an engaging manner. An accompanying guide provided background information, discussion starters, and engaging activities for students and adults alike. Subtitles in German and Italian were used on each of the video journals in addition to the English narrative, and the resulting product was entitled, ANDRILL: A REAL WORLD GEOSCIENCE ADVENTURE. The primary objective was to introduce teachers, students, and the general public to Antarctica and the ANDRILL Program, and to provide preliminary insights into the following questions: How do scientists from around the world come together in the coldest, windiest, driest place on Earth to uncover the secrets that have been shrouded beneath the ice for millions of years? What secrets do the rocks record? How can I join the journey to learn more about Antarctica and ANDRILL?

Multiple Perspectives on the Topic of Scientists and Education and Public Outreach

NASA Astrophysics Data System (ADS)

Peticolas, L. M.

2011-12-01

This presentation aims to share the author's understanding of the complex topic of scientist involvement in and attitudes about Education and Public Outreach (E/PO) by approaching the topic from four viewpoints. The first perspective is from the author's own journey starting as a post-doctoral fellow engaged in limited ways in education and public outreach to full-time E/PO professional. The second perspective comes from discussions with scientists on the topic of E/PO. Evaluation data of scientists' involvement in a community college space science seminar series provides a third perspective. And the final perspective approaches the topic from the vantage point of research on scientist involvement in E/PO. From these multiple perspectives, there is evidence that that there exists ample passion for education and outreach in the scientific community. However, the path from passion to meaningful engagement of audiences and understandings of educational pedagogies continues to be difficult for a variety of reasons, such as: 1) a tendency to teach as one was taught rather than changing teaching practices based on research on how people learn, 2) a lack of time to collaborate and partner with appropriate educational professionals or institutions, 3) a lack of awareness (or a lack of time to develop an awareness) of an audience need or audience baseline understandings, and 4) a belief that science is supra-cultural and can be shared outside of a cultural context. It is suggested that the most effective way for scientists to engage in E/PO is to develop professional relationships with educators in the field of education and outreach for which the scientist is passionate (such as a middle school teacher if the passion lies in sharing science with middle school students.) E/PO professionals can also support and guide the passion with an understanding of best practices in E/PO. Spending time within the culture of the audience one wishes to work with can also be helpful in order to understand the view of science from within that culture. It has also been observed that professional evaluators have made excellent partners with scientists when scientists desire to move passion to meaningful engagement. This is likely to be because evaluators help to guide education efforts to meet goals and objectives set out in education programs and projects.

How Not to Write for Peer-Reviewed Publications: Talking to Everyone Else

NASA Astrophysics Data System (ADS)

Reddy, C. M.; Lippsett, L.

2012-12-01

In an era when pressing societal issues demand scientific knowledge, science deniers and deriders are increasing, science education is deteriorating, and science in traditional media is diminishing. Scientists are challenged more than ever to explain their work beyond their peers, but they are not encouraged nor trained to do this. Rather, they can be isolated from society at large and trained to communicate in a prescribe style that the public often finds incomprehensible or can't relate to. We created a voluntary course for graduate students in the MIT/WHOI Joint Program in Oceanography to encourage young scientists to venture beyond their laboratories and add much-needed clear and accurate scientific information to critical issues under public debate. The course is team-taught by a scientist with extensive experience dealing with the media, policymakers, legislators, and benefactors, and a journalist with decades of experience writing about science and working with scientists. Together, we expose students to the cultures, perspectives, motivations, and timelines of various stakeholders with whom they may communicate. With guests that include graphic designers, web gurus, and working journalists, the students learn editorial processes and skills to enhance effective communication with non-scientists, including the use of graphics, illustrations, photography and multimedia. Each student is also connected with a mentor: a working science journalist who volunteers personal attention throughout the student's process of writing an article explaining their research. (e.g. Dick Kerr of /Science/ and Peter Spotts of /The Christian Science Monitor/). In short, the course helps students become comfortable and facile outside the ivory tower.

The AirWaterGas Teacher Professional Development Program: Lessons Learned by Pairing Scientists and Teachers to Develop Curriculum on Global Climate Change and Regional Unconventional Oil and Gas Development

NASA Astrophysics Data System (ADS)

Gardiner, L. S.; Hatheway, B.; Rogers, J. D.; Casey, J. G.; Lackey, G.; Birdsell, D.; Brown, K.; Polmear, M.; Capps, S.; Rosenblum, J.; Sitterley, K.; Hafich, K. A.; Hannigan, M.; Knight, D.

2015-12-01

The AirWaterGas Teacher Professional Development Program, run by the UCAR Center for Science Education, brought together scientists and secondary science teachers in a yearlong program culminating in the development of curriculum related to the impacts of unconventional oil and gas development. Graduate students and research scientists taught about their research area and its relationship to oil and gas throughout three online courses during the 2015-16 school year, during which teachers and scientists engaged in active online discussions. Topics covered included climate change, oil and gas infrastructure, air quality, water quality, public health, and practices and policies relating to oil and gas development. Building upon their initial online interactions and a face-to-face meeting in March, teachers were paired with appropriate AirWaterGas team members as science advisors during a month-long residency in Boulder, Colorado. During the residency, graduate student scientists provided resources and feedback as teachers developed curriculum projects in collaboration with each other and UCAR science educators. Additionally, teachers and AirWaterGas researchers shared experiences on an oil and gas well site tour, and a short course on drilling methods with a drilling rig simulator. Here, we share lessons learned from both sides of the aisle, including initial results from program assessment conducted with the participating teachers.

Connecting Resources for Tertiary Chemical Education with Scientists and Students in Developing Countries

ERIC Educational Resources Information Center

Jansen-van Vuuren, Ross D.; Buchanan, Malcolm S.; McKenzie, Ross H.

2013-01-01

The ability of developing countries to provide a sound tertiary chemical education is a key ingredient to the improvement of living standards and economic development within these countries. However, teaching undergraduate experimental chemistry and building research capacity in institutions based within these countries involves formidable…

Students' Experience in a General Chemistry Cooperative Problem Based Laboratory

ERIC Educational Resources Information Center

Sandi-Urena, Santiago; Cooper, Melanie M.; Gatlin, Todd A.; Bhattacharyya, Gautam

2011-01-01

Most educators and scientists would agree that science laboratory instruction has the potential of developing science practices fundamental to achieving scientific literacy. However, there is scant evidence to support that this potential is realized, particularly in tertiary level education. This paper reports qualitative results from a sequential…

Challenges of Recruiting Candidates with Strong Academic Credentials

ERIC Educational Resources Information Center

Denton, Jon; Davis, Trina

2007-01-01

A major challenge to improving science education lies in the shortage of qualified science teachers. A potential solution to this challenge consists of directing the energy and talent of graduate students and postdoctoral scientists to reinvigorate science education in schools. This requires creating new, more accessible pathways for science…

Research and Teaching: Toward Interdisciplinary Perspectives--Using Osmotic Pressure as an Example for Analyzing Textbook Explanations

ERIC Educational Resources Information Center

Sung, Shannon; Shen, Ji; Stanger-Hall, Kathrin F.; Wiegert, Craig; Li, Wan-l; Brown, Scott; Robertson, Tom

2015-01-01

Despite the increasing interests and practices in interdisciplinary science education, little research has been documented to develop effective assessments targeting students' interdisciplinary learning. In response to this gap, a team of scientists and educators developed an interdisciplinary assessment instrument targeting osmosis, which was…

Understanding adolescent student perceptions of science education

NASA Astrophysics Data System (ADS)

Ebert, Ellen Kress

This study used the Relevance of Science Education (ROSE) survey (Sjoberg & Schreiner, 2004) to examine topics of interest and perspectives of secondary science students in a large school district in the southwestern U.S. A situated learning perspective was used to frame the project. The research questions of this study focused on (a) perceptions students have about themselves and their science classroom and how these beliefs may influence their participation in the community of practice of science; (b) consideration of how a future science classroom where the curriculum is framed by the Next Generation Science Standards might foster students' beliefs and perceptions about science education and their legitimate peripheral participation in the community of practice of science; and (c) reflecting on their school science interests and perspectives, what can be inferred about students' identities as future scientists or STEM field professionals? Data were collected from 515 second year science students during a 4-week period in May of 2012 using a Web-based survey. Data were disaggregated by gender and ethnicity and analyzed descriptively and by statistical comparison between groups. Findings for Research Question 1 indicated that boys and girls showed statistically significant differences in scientific topics of interest. There were no statistical differences between ethnic groups although. For Research Question 2, it was determined that participants reported an increase in their interest when they deemed the context of the content to be personally relevant. Results for Research Question 3 showed that participants do not see themselves as youthful scientists or as becoming scientists. While participants value the importance of science in their lives and think all students should take science, they do not aspire to careers in science. Based on this study, a need for potential future work has been identified in three areas: (a) exploration of the perspectives and interests of non-mainstream students and urban students whose representation in this study was limited; (b) investigation of topics where students expressed low interests topics; and (c) development and design of authentic communities of practice in the science classroom.

ARES Education and Public Outreach

NASA Technical Reports Server (NTRS)

Allen, Jaclyn; Galindo, Charles; Graff, Paige; Willis, Kim

2014-01-01

The ARES Directorate education team is charged with translating the work of ARES scientists into content that can be used in formal and informal K-12 education settings and assisting with public outreach. This is accomplished through local efforts and national partnerships. Local efforts include partnerships with universities, school districts, museums, and the Lunar and Planetary Institute (LPI) to share the content and excitement of space science research. Sharing astromaterials and exploration science with the public is an essential part of the Directorate's work. As a small enclave of physical scientists at a NASA Center that otherwise emphasizes human space operations and engineering, the ARES staff is frequently called upon by the JSC Public Affairs and Education offices to provide presentations and interviews. Scientists and staff actively volunteer with the JSC Speaker's Bureau, Digital Learning Network, and National Engineers Week programs as well as at Space Center Houston activities and events. The education team also participates in many JSC educator and student workshops, including the Pre-Service Teacher Institute and the Texas Aerospace Scholars program, with workshop presentations, speakers, and printed materials.

Cancer Cell Biology: A Student-Centered Instructional Module Exploring the Use of Multimedia to Enrich Interactive, Constructivist Learning of Science

PubMed Central

Bockholt, Susanne M.; West, J. Paige; Bollenbacher, Walter E.

2003-01-01

Multimedia has the potential of providing bioscience education novel learning environments and pedagogy applications to foster student interest, involve students in the research process, advance critical thinking/problem-solving skills, and develop conceptual understanding of biological topics. Cancer Cell Biology, an interactive, multimedia, problem-based module, focuses on how mutations in protooncogenes and tumor suppressor genes can lead to uncontrolled cell proliferation by engaging students as research scientists/physicians with the task of diagnosing the molecular basis of tumor growth for a group of patients. The process of constructing the module, which was guided by scientist and student feedback/responses, is described. The completed module and insights gained from its development are presented as a potential “multimedia pedagogy” for the development of other multimedia science learning environments. PMID:12822037

TRIENNIAL REPRODUCTION SYMPOSIUM: American Society of Animal Science L. E. Casida Award for Excellence in Graduate Education: Thoughts on mentoring graduate students in reproductive biology.

PubMed

Smith, M F

2016-07-01

Programs in animal science are particularly well suited for graduate education because students can receive comprehensive training in the laboratory as well as with the whole animal. Furthermore, graduate students in animal science have the opportunity to understand how their research relates to a real world problem. Graduate students need to take ownership of their education by identifying training goals, choosing a mentor who will help them achieve their goals, and becoming engaged in research as soon as possible. In my own graduate program, I emphasize concepts more than techniques and I believe that graduate course work should focus on the basic areas of science that underlie reproductive biology (e.g., endocrinology, biochemistry, physiology, immunology, and statistics). Based on the increase in technology available for scientific investigation and the diversity of expertise required to address important research problems, graduate students need to learn the importance of establishing productive collaborations and begin building a scientific network. Preparation for graduate school frequently begins early with a curiosity and passion for understanding how biology works. Undergraduate courses can facilitate scientific thinking by providing opportunities in lectures and laboratories for students to transition from passive learners to thinking of themselves as animal scientists. There is a profound difference between individuals who view themselves as practitioners of a discipline and those who are simply trying to complete a course requirement. Teachers of undergraduate courses should incorporate experiential learning exercises into their lectures and laboratories to provide undergraduate students the opportunity to function as animal scientists and to embrace their scientific education. Graduate training has been the most enjoyable aspect of my career and it has been a joy to witness the achievements of students following completion of their degree!

Better Communication Through Collaboration: Lessons Learned from a New Model of Science Communication Education

NASA Astrophysics Data System (ADS)

Hayden, T.

2011-12-01

Direct, effective communication with the public is an increasingly important part of the earth scientist's professional toolkit. Earth sciences issues, including climate change, ocean acidification, energy extraction and use and geological hazard assessment, are increasingly relevant to public debates, yet recent, dramatic changes in the media business have led to decreased coverage of science. Earth scientists must increasingly shoulder the burden of informing the broad public themselves, and in collaboration with professional communicators. Fortunately, the tools and venues needed to do so have never been more accessible. This presentation will describe a new model of science communication education, based on bringing together collaborating teams of students with diverse backgrounds in the sciences, engineering and journalism. The project-based approach uses group workshopping and multiple rounds of peer- and instructor-guided revision to leverage diverse expertise and facilitate both primary knowledge gain and comprehensive, effective and meaningful training and experience in audience-focused outreach, media interaction, and journalism. Courses build from fundamental communications theory to the end goal of publication in professional outlets. Course goals are regularly enhanced and reinforced with internships and individual study projects. Using examples from a series of courses and projects developed at Stanford University over the past three years, I will describe the theory and strategies underlying this new approach to science communication education, what it has to offer for scientists and journalists alike, and key points to consider for effective implementation. I will also show how combining the knowledge, expertise and experience of STEM and journalism students can inform a new model of science journalism, based on exploring and communicating the process of science, not just the results, that can avoid many of the common pitfalls of science journalism. I will present a preliminary assessment of outcomes from three courses at Stanford - environmental communications, environmental journalism and multimedia storytelling for earth scientists - including publications, retrospective post assessment of student abilities and attitudes, and ongoing application of course goals in professional and/or educational settings.

Stereotyping at the undergraduate level revealed during interprofessional learning between future doctors and biomedical scientists.

PubMed

Lewitt, Moira S; Ehrenborg, Ewa; Scheja, Max; Brauner, Annelie

2010-01-01

Interprofessional education (IPE) involving undergraduate health professionals is expected to promote collaboration in their later careers. The role of IPE between doctors and biomedical scientists has not been explored at the undergraduate level. Our aim was to introduce IPE sessions for medical and biomedical students in order to identify the benefits and barriers to these groups learning together. Medical and biomedical students together discussed laboratory results, relevant literature, and ideas for developing new diagnostic tools. The programme was evaluated with questionnaires and interviews. While there was general support for the idea of IPE, medical and biomedical students responded differently. Biomedical students were more critical, wanted more explicit learning objectives and felt that their professional role was often misunderstood. The medical students were more enthusiastic but regarded the way the biomedical students communicated concerns about their perceived role as a barrier to effective interprofessional learning. We conclude that stereotyping, which can impede effective collaborations between doctors and biomedical scientists, is already present at the undergraduate level and may be a barrier to IPE. Effective learning opportunities should be supported at the curriculum level and be designed to specifically enable a broad appreciation of each other's future professional roles.

Students Engaged in Climate Change Research Through Vegetation Phenology Studies

NASA Astrophysics Data System (ADS)

Sparrow, E. B.; Verbyla, D. L.; White, M. A.; Gordon, L. S.

2004-12-01

The project goal is to engage students in scientific research as a way of learning science, math, and technology in K-12 classrooms by providing an opportunity for student-scientist collaborations. This NSF-funded GLOBE project is of significance to scientists who track plant phenological changes as an indicator of climate change and study carbon cycling. To students it is a means of studying Earth as a system. Plants and their phenology stages reflect and integrate the effects of weather and other environmental parameters that are components of the Earth system. Remotely sensed data indicate that the plant growing season has increased in northern latitudes. The greenness estimates could vary due to possible interference from clouds and other atmospheric properties, low sun angles at high latitudes and aging of satellite detectors; hence the need for ground-based observations to help validate satellite-derived estimates of plant growing season lengths. GLOBE plant phenology measurements (protocols) of Green-up and Green-down for deciduous trees and shrubs, and for grasses were developed at the University of Alaska Fairbanks, and Budburst at Utah State University. These were pilot- tested, and revised several times with input from teachers and GLOBE personnel. Learning activities to support understanding of science concepts, were also developed and/or adapted. The protocols and learning activities were aligned to national science standards and incorporated in the "Earth as a System" chapter in the 2003 GLOBE Teacher Guide published and also posted on the GLOBE website (www.globe.gov). Phenology protocols and learning activities are being used in Alaska by teachers and students who participate in different NSF and NASA-funded science education programs, such as the Schoolyard Long Term Ecological Research Project, the Global Change Education Using Western Science and Native Observations (OLCG) Project, the Alaska GLOBE program and the EPSCoR Rural Research Partnership Education Outreach program. Pre-college students and their teachers from 77 schools in 11 countries have engaged in GLOBE plant phenology research and entered phenology data on the GLOBE web server. Thus, collaborative efforts in research and education among science education projects in Alaska and in other countries have been facilitated. Scientists now have access to global plant phenology data-ground-based observations that previously have been very rare. Students have also used the phenology protocols for their own investigations.

Live Ship-to-shore Video Events from the JOIDES Resolution during International Ocean Discovery Program Expeditions

NASA Astrophysics Data System (ADS)

Kulhanek, D. K.; Cooper, S. K.; Dadd, K. A.; Colwell, F. S.; Mote, A. S.; Christiansen, E. A.

2014-12-01

The International Ocean Discovery Program (IODP) cores sediment and rock below the seafloor during two-month expeditions to study Earth's history and dynamics. Most IODP expeditions sail dedicated education officers to lead outreach efforts, including live ship-to-shore video events. Expeditions conduct 30-90 events through close collaboration between the educators and science party members. In 2014, Expedition 349 collected cores in the South China Sea. Even though no educator sailed, the staff scientist filled this role, allowing the expedition to carry out an extensive program of 58 live events (led by scientists) with institutions in 13 countries, demonstrating that outreach is deeply engrained in IODP culture. Expedition 349 spoke to ~3700 people, including ~375 primary school students in China and the USA, ~1150 secondary school students in six countries, and ~1300 undergraduate and graduate students in seven countries. The scientists also conducted events with museums, science centers, and science conferences. Over the last six years of operations, we have gained significant insights that help us to capitalize on best practices and utilize the newest and most effective technology for live events from sea given bandwidth constraints. We currently conduct video events with an iPad using Zoom software. Educators and scientists work together to provide ship tours and educate audiences about expedition science, lab work, and life at sea, and also answer audience questions. One feature we use extensively is the ability to screen share with Zoom, which allows us to show images stored on the iPad. These images show the location of drill sites and provide background information about the expedition scientific objectives, the drilling and coring process, and more. Shipboard scientists are usually enthusiastic about outreach events and many contact friends and colleagues to schedule additional events. The audiences we connect with ask many great questions and often post photos and YouTube videos of the events to social media. In addition, we conduct surveys following each event to help us improve our outreach program. We apply these results to future expeditions, including Expedition 353 (Indian Monsoon), which will be at sea during AGU, giving us the opportunity to demonstrate our ship-to-shore capabilities.

Earthworks: Educating Teachers in Earth System Sciences

NASA Technical Reports Server (NTRS)

Spetzler, H.; Weaver, A.; Buhr, S.

2000-01-01

Earthworks is a national community of teachers and scientists. Initiated in 1998 with funding from NASA, our summer workshops in the Rocky Mountains each year provide unique opportunities for teachers to design and conduct field research projects, working closely with scientists. Teachers then develop plans for classroom implementation during the school year, sharing their ideas and experiences with other community members through e-mail and a listserv. Scientists, from graduate students to expert senior researchers, share their knowledge of field methods in environmental science, and learn how to better communicate and teach about their research.

Deep understanding of electromagnetism using crosscutting concepts

NASA Astrophysics Data System (ADS)

De Poorter, John; De Lange, Jan; Devoldere, Lies; Van Landeghem, Jouri; Strubbe, Katrien

2017-01-01

Crosscutting concepts like patterns and models are fundamental parts in both the American framework of science education (from the AAAS) and our proposals for a new science education framework in Flanders. These concepts deepen the insight of both students and teachers. They help students to ask relevant questions during an inquiry and they give an understanding in how scientists built up their scientific theories. We illustrate the didactical possibilities of crosscutting concepts within the field of electromagnetism.

"Got Snow?" Education and Outreach for the IPY

NASA Astrophysics Data System (ADS)

Turrin, M.; Bell, R. E.; Pfirman, S.; Maru, P.

2004-12-01

The "Bridging the Poles: Education Linked with Research" workshop of June 23-25, brought together an international group of 65 scientists, educators and media specialists to define strategies to engage the next generation of polar scientists, engineers and leaders, and inspire the general public. The workshop results emphasized the need to leverage emerging science programs with meaningful education and outreach programming that is rolled out to the public as major media events. Participants advocated a broad interdisciplinary approach, recognizing that the poles have a rich cultural heritage and fascinating history. Linking research events with student fascination about polar environments, peoples and histories of exploration, can help improve science, math, reading, and other skills. Distance learning with web course delivery is a powerful tool to reach advanced students and to help develop a new generation of researchers among Arctic indigenous peoples. Successful examples of this approach include the University of the Arctic's PhD network, and collaborative field courses. Field experiences build life-long advocates of the poles for students, teachers, and the media alike. Establishing connections among scientists, educators and informal outreach venues in their own community, can have long-lasting impact. "Think Globally/Act Locally" and the complementary "Think Locally/Act Globally" will be important themes for local, national and international IPY programming. Imagine a semi-trailer truck labeled "Got Snow?" traversing the country loaded with polar gear, interactive activities and a snowmaker; polar exhibitions opening at natural history and art museums and zoos; polar-themed postage stamps; national polar book-of-the-month recommendations; made-for-TV polar documentaries; and a rich, multidisciplinary and multilingual web portal. To meet these opportunities requires coordination, linking communities, and high-bandwidth access to high quality content from the polar regions. We need to start now to develop an integrated research/media/education strategy; establish partners among the research, media, and education communities; and diversify participation and audiences.

Scientific Inquiry Based Professional Development Models in Teacher Education

ERIC Educational Resources Information Center

Corlu, Mehmet Ali; Corlu, M. Sencer

2012-01-01

Scientific inquiry helps students develop critical thinking abilities and enables students to think and construct knowledge like a scientist. The study describes a method course implementation at a major public teachers college in Turkey. The main goal of the course was to improve research and teaching abilities of prospective physics teachers…

Computerized Writing and Reading Instruction for Students in Grades 4-9 with Specific Learning Disabilities Affecting Written Language

ERIC Educational Resources Information Center

Tanimoto, S.; Thompson, R.; Berninger, V. W.; Nagy, W.; Abbott, R. D.

2015-01-01

Computer scientists and educational researchers evaluated effectiveness of computerized instruction tailored to evidence-based impairments in specific learning disabilities (SLDs) in students in grades 4-9 with persisting SLDs despite prior extra help. Following comprehensive, evidence-based differential diagnosis for dysgraphia (impaired…

Case Study III: The University of Washington and Bellevue School District Partnership

ERIC Educational Resources Information Center

Coburn, Cynthia E.; Penuel, William R.; Geil, Kimberly E.

2015-01-01

This design-research partnership involves learning scientists, design researchers, and graduate students from the Learning in Informal and Formal Environments (LIFE) Center and the College of Education at the University of Washington (UW), and district staff, teachers, and students from the Bellevue School District (BSD). The goal of their work is…

Helping Students Understand Real Capacitors: Measuring Efficiencies in a School Laboratory

ERIC Educational Resources Information Center

Carvalho, Paulo Simeao; Sampaio e Sousa, Adriano

2008-01-01

A recent reform in the Portuguese secondary school curriculum reintroduced the study of capacitors. Thus we decided to implement some experimental activities on this subject with our undergraduate students in physics education courses. A recent announcement of a new kind of capacitor being developed by a team of scientists at Massachusetts…

Cases on Research-Based Teaching Methods in Science Education

ERIC Educational Resources Information Center

de Silva, Eugene, Ed.

2015-01-01

While the great scientists of the past recognized a need for a multidisciplinary approach, today's schools often treat math and science as subjects separate from the rest. This not only creates a disinterest among students, but also a potential learning gap once students reach college and then graduate into the workforce. "Cases on…

GLOBE ONE: A Community-Based Environmental Field Campaign

Treesearch

Rebecca Boger; Peggy LeMone; John McLaughlin; Sharon Sikora; Sandra Henderson

2006-01-01

The Global Learning and Observations to Benefit the Environment (GLOBE) program is an international environmental science and education program involving scientists, teachers and students in the collection, analysis, and display of data used in environmental monitoring and research. Since its formation in 1994, students have collected over 11 million data points in...

The Implications of the Cognitive Sciences for the Relation Between Religion and Science Education: The Case of Evolutionary Theory

NASA Astrophysics Data System (ADS)

Blancke, Stefaan; De Smedt, Johan; De Cruz, Helen; Boudry, Maarten; Braeckman, Johan

2012-08-01

This paper discusses the relationship between religion and science education in the light of the cognitive sciences. We challenge the popular view that science and religion are compatible, a view that suggests that learning and understanding evolutionary theory has no effect on students' religious beliefs and vice versa. We develop a cognitive perspective on how students manage to reconcile evolutionary theory with their religious beliefs. We underwrite the claim developed by cognitive scientists and anthropologists that religion is natural because it taps into people's intuitive understanding of the natural world which is constrained by essentialist, teleological and intentional biases. After contrasting the naturalness of religion with the unnaturalness of science, we discuss the difficulties cognitive and developmental scientists have identified in learning and accepting evolutionary theory. We indicate how religious beliefs impede students' understanding and acceptance of evolutionary theory. We explore a number of options available to students for reconciling an informed understanding of evolutionary theory with their religious beliefs. To conclude, we discuss the implications of our account for science and biology teachers.

The role of models/and analogies in science education: implications from research

NASA Astrophysics Data System (ADS)

Coll, Richard K.; France, Bev; Taylor, Ian

2005-02-01

Models and modelling are key tools for scientists, science teachers and science learners. In this paper we argue that classroom-based research evidence demonstrates that the use of models and analogies within the pedagogy of science education may provide a route for students to gain some understanding of the nature of science. A common theme to emerge from the literature reviewed here is that in order to successfully develop conceptual understandings in science, learners need to be able to reflect on and discuss their understandings of scientific concepts as they are developing them. Pedagogies that involve various types of modelling are most effective when students are able to construct and critique their own and scientists' models. Research also suggests that group work and peer discussion are important ways of enhancing students' cognitive and metacognitive thinking skills. Further we argue that an understanding of science models and the modelling process enables students to develop a metacognitive awareness of knowledge development within the science community, as well as providing the tools to reflect on their own scientific understanding.

PIRE Experience Reaches out to the Russian Far East and Augments Graduate Education Abroad

NASA Astrophysics Data System (ADS)

Almberg, L. D.; Eichelberger, J. C.; Izbekov, P.; Ushakov, S.; Vesna, E.

2006-12-01

NSF's Partners in International Research and Education (PIRE) program seeks to introduce American students to collaborative international science early in their graduate careers. The intent is that the next generation of American scientists will be better prepared to work at the international level. The emphases on partnership and learning about the culture of the host country is a welcome and productive change from the `grab and dash' approach that can characterize `Winter national' projects. Our PIRE project, US-Russia-Japan Partnership in Volcanological Research and Education, is an interdisciplinary investigation of the magma systems at Bezymianny and Shiveluch Volcanoes in Kamchatka, Russia and Mount St Helens in Washington, USA. We wish to understand how massive edifice collapse at all three volcanoes perturbed the magma systems and influenced subsequent and continuing eruptive behavior. Seven American graduate students from the universities of Alaska, Hawaii, Washington, Oregon, and Stanford embarked on a personal and professional development adventure in July and August, 2006. Their experience began in Fairbanks, AK with preparations for remote foreign field work and research planning with mentor scientists. The adventure continued in Petropavlosk-Kamchatsky, Kamchatka, which required circumnavigation of the world as no airlines fly between Anchorage and Petropavlovsk. Faculty at Kamchatka State University provided intensive short courses for two weeks, introducing students to Russian language, culture, geography and history while they adjusted to the new environment and met Russian counterparts at the Institute of Volcanology and Seismology. Afternoon discussions with Russian experts in volcanology, seismology, tectonics and tephrachronology were enlightening and influenced the research plans. Russian graduate and advanced undergraduate students joined the group at the helicopter accessed camp on Bezymianny volcano. Two young Russian scientists headed the field team. Students learned from one another and the accompaning senior scientists. This year of the five-year program was focused on sampling for petrology and geochemistry and establishment of continuous GPS sites. The team conducted the first work on products of the large eruption of May 9, 2006. The experience concluded with a one-week visit to Mount St Helens and the Cascade Volcano Observatory for a workshop with American students and scientists working on the current eruption there. Next year a new team will be fielded on a similar schedule. However, we will keep the 2006 team together with web-based video conferencing as the work progresses through laboratory analysis and interpretation and publication of results.

Meeting the Technology Portion of the Science and Technology Goal of Quality Education.

ERIC Educational Resources Information Center

Pennsylvania State Dept. of Education, Harrisburg. Bureau of Curriculum Services.

One of the goals of quality education in Pennsylvania is to help every student acquire knowledge, understanding, and appreciation of science and technology. This publication, which focuses on the technology component of this goal, is an initial effort by a team of scientists and science educators to define technology as it should be presented in…

Teaching Experiences for Graduate Student Researchers: A Study of the Design and Implementation of Science Courses for Secondary Students

ERIC Educational Resources Information Center

Collins, Anne Wrigley

2011-01-01

Modern science education reform recommends that teachers provide K-12 science students a more complete picture of the scientific enterprise, one that lies beyond content knowledge and centers more on the processes and culture of scientists. In the case of Research Experience for Teachers (RET) programs, the "teacher" becomes "researcher" and it is…

The NASA SMD Science Education and Public Outreach Forums: Engaging Scientists in NASA Education and Public Outreach

NASA Astrophysics Data System (ADS)

Smith, Denise A.; Peticolas, L.; Schwerin, T.; Shipp, S.

2014-01-01

The NASA Science Mission Directorate (SMD) Education and Public Outreach (E/PO) program provides a direct return on the public’s investment in NASA’s science missions and research programs through a comprehensive suite of educational resources and opportunities for students, educators, and the public. Four Science Education and Public Outreach Forums work with SMD-funded missions, research programs, and grantees to organize individual E/PO activities into a coordinated, effective, and efficient nationwide effort, with easy entry points for scientists, educators, and the public. We outline the Forums’ role in 1) facilitating communication and collaboration among SMD E/PO programs, scientists, and educators; 2) supporting utilization of best practices and educational research; 3) creating clear paths of involvement for scientists interested in SMD E/PO; and, 4) enabling efficient and effective use of NASA content and education products. Our work includes a cross-Forum collaboration to inventory existing SMD education materials; identify and analyze gaps; and interconnect and organize materials in an accessible manner for multiple audiences. The result is NASAWavelength.org, a one-stop-shop for all NASA SMD education products, including tools to help users identify resources based upon their needs and national education standards. The Forums have also collaborated with the SMD E/PO community to provide a central point of access to metrics, evaluation findings, and impacts for SMD-funded E/PO programs (http://smdepo.org/page/5324). We also present opportunities for the astronomy community to participate in collaborations supporting NASA SMD efforts in the K - 12 Formal Education, Informal Education and Outreach, Higher Education and Research Scientist communities. See Bartolone et al., Lawton et al., Meinke et al., and Buxner et al. (this conference), respectively, to learn about Forum resources and opportunities specific to each of these communities.

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

NASA Astrophysics Data System (ADS)

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

2011-12-01

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

Learning science and science education in a new era.

PubMed

Aysan, Erhan

2015-06-01

Today, it takes only a few months for the amount of knowledge to double. The volume of information available has grown so much that it cannot be fully encompassed by the human mind. For this reason, science, learning, and education have to change in the third millennium. The question is thus: what is it that needs to be done? The answer may be found through three basic stages. The first stage is persuading scientists of the necessity to change science education. The second stage is more difficult, in that scientists must be told that they should not place an exaggerated importance on their own academic field and that they should see their field as being on an equal basis with other fields. In the last stage, scientists need to condense the bulk of information on their hands to a manageable size. "Change" is the magic word of our time. Change brings about new rules, and this process happens very quickly in a global world. If we scientists do not rapidly change our scientific learning and education, we will find our students and ourselves caught up in an irreversibly destructive and fatal change that sets its own rules, just like the Arab spring.

Dive and discover: Expeditions to the seafloor

NASA Astrophysics Data System (ADS)

Lawrence, Lisa Ayers

The Dive and Discover Web site is a virtual treasure chest of deep sea science and classroom resources. The goals of Dive and Discover are to engage students, teachers, and the general public in the excitement of ocean disco very through an interactive educational Web site. You can follow scientists on oceanographic research cruises by reading their daily cruise logs, viewing photos and video clips of the discoveries, and even e-mailing questions to the scientists and crew. WHOI has also included an “Educator's Companion” section with teaching strategies, activities, and assessments, making Dive and Discover an excellent resource for the classroom.

Dive and discover: Expeditions to the seafloor

NASA Astrophysics Data System (ADS)

Ayers Lawrence, Lisa

The Dive and Discover Web site is a virtual treasure chest of deep sea science and classroom resources. The goals of Dive and Discover are to engage students, teachers, and the general public in the excitement of ocean disco very through an interactive educational Web site. You can follow scientists on oceanographic research cruises by reading their daily cruise logs, viewing photos and video clips of the discoveries, and even e-mailing questions to the scientists and crew. WHOI has also included an "Educator's Companion" section with teaching strategies, activities, and assessments, making Dive and Discover an excellent resource for the classroom.

Socio-ethical education in nanotechnology engineering programmes: a case study in Malaysia.

PubMed

Balakrishnan, Balamuralithara; Er, Pek Hoon; Visvanathan, Punita

2013-09-01

The unique properties of nanotechnology have made nanotechnology education and its related subjects increasingly important not only for students but for mankind at large. This particular technology brings educators to work together to prepare and produce competent engineers and scientists for this field. One of the key challenges in nanotechnology engineering is to produce graduate students who are not only competent in technical knowledge but possess the necessary attitude and awareness toward the social and ethical issues related to nanotechnology. In this paper, a research model has been developed to assess Malaysian nanotechnology engineering students' attitudes and whether their perspectives have attained the necessary objectives of ethical education throughout their programme of study. The findings from this investigation show that socio ethical education has a strong influence on the students' knowledge, skills and attitudes pertaining to socio ethical issues related to nanotechnology.

Science Identity in Informal Education

NASA Astrophysics Data System (ADS)

Schon, Jennifer A.

The national drive to increase the number of students pursuing Science Technology, Engineering, and Math (STEM) careers has brought science identity into focus for educators, with the need to determine what encourages students to pursue and persist in STEM careers. Science identity, the degree to which students think someone like them could be a scientist is a potential indicator of students pursuing and persisting in STEM related fields. Science identity, as defined by Carlone and Johnson (2007) consists of three constructs: competence, performance, and recognition. Students need to feel like they are good at science, can perform it well, and that others recognize them for these achievements in order to develop a science identity. These constructs can be bolstered by student visitation to informal education centers. Informal education centers, such as outdoor science schools, museums, and various learning centers can have a positive impact on how students view themselves as scientists by exposing them to novel and unique learning opportunities unavailable in their school. Specifically, the University of Idaho's McCall Outdoor Science School (MOSS) focuses on providing K-12 students with the opportunity to learn about science with a place-based, hands-on, inquiry-based curriculum that hopes to foster science identity development. To understand the constructs that lead to science identity formation and the impact the MOSS program has on science identity development, several questions were explored examining how students define the constructs and if the MOSS program impacted how they rate themselves within each construct. A mixed-method research approach was used consisting of focus group interviews with students and pre, post, one-month posttests for visiting students to look at change in science identity over time. Results from confirmatory factor analysis indicate that the instrument created is a good fit for examining science identity and the associated constructs for students attending the MOSS residential program. Analysis of results from paired-samples t-test indicates that MOSS does contribute to a positive change in science identity and this change does persist one month following the visit to MOSS, although a slight decline is seen. The results from this research and creation of this instrument provide useful tools for educators interested in increasing their students' science identity.

CosmoQuest: Supporting Subject Matter Experts in Broadening the Impacts of their Work beyond their Institutional Walls.

NASA Astrophysics Data System (ADS)

Noel-Storr, J.; Buxner, S.; Grier, J.; Gay, P.

2016-12-01

CosmoQuest is a virtual research facility, which, like its physical counterparts, provides tools for scientists to acquire reduced data products (thanks to our cadre of citizen scientists working to analyze images and produce results online), and also to participate in education and outreach activities either directly through CosmoQuest activities (such as CosmoAcademy and the Educators' Zone) or with the support of CosmoQuest. Here, we present our strategies to inspire, engage and support Subject Matter Experts (SMEs - Scientists, Engineers, Technologists and Mathematicians) in activities outside of their institutions, and beyond college classroom teaching. We provide support for SMEs who are interested in increasing the impacts of their science knowledge and expertise by interacting with people online, or in other venues outside of their normal work environment. This includes a broad spectrum of opportunities for those interested in hosting webinars; running short courses for the public; using Facebook, Twitter or other social media to communicate science; or other diverse activities such as supporting an open house, science fair, or star party. As noted by Katheryn Woods-Townsend and colleagues, "...face-to-face interactions with scientists allowed students to view scientists as approachable and normal people, and to begin to understand the range of scientific areas and careers that exist. Scientists viewed the scientist-student interactions as a vehicle for science communication" (2015). As CosmoQuest fosters these relationships, it We present a framework for SMEs which combine opportunities for continuing professional development (virtually and in person at conferences) with ongoing online support, creating a dynamic professional learning network. The goal of this is to deepen SME capacity-knowledge, attitudes and behaviors-both encouraging and empowering them to connect to broader audiences in new ways.

KSC-2011-3364

NASA Image and Video Library

2011-05-06

Cape Canaveral, Fla. -- Students from across the nation gathered at NASA's Kennedy Space Center in Florida for the NASA Explorer Schools (NES) symposium. In the Center for Space Education at Kennedy, a student participates in a hands-on activity as an education specialist looks on. During the NES event, students presented their investigation project to their peers, scientists, engineers and education specialists. About 60 fourth- through 12-grade students nationwide are at the center May 4-7 participating in tours of processing and launch facilities and the U.S. Astronaut Hall of Fame, as well as several educational activities and a career panel question-and-answer session. About 30 teachers will receive professional development opportunities during the symposium. The participants were competitively selected after they completed an original investigation focused on existing NASA missions or research interests. Photo Credit: NASA/Kim Shiflett

Building Bridges Between IPY Scientists and the Educational Community: A Spectrum of IPY Education and Outreach Activities

NASA Astrophysics Data System (ADS)

Ledley, T. S.; Dahlman, L.; McAuliffe, C.; Domenico, B.; Taber, M. R.

2006-12-01

The International Polar Year is an opportunity to simultaneously increase our scientific understanding of the polar regions and to engage the next generation of Earth scientists and socially responsible citizens. However, building the bridge between the scientific community who conduct the research and the education community who convey that information to students requires specific and continuing efforts. The Earth Exploration Toolbook (EET, http://serc.carleton.edu/eet) and the accompanying spectrum of activities encompassing development of materials that can provide access and understanding of IPY data and knowledge, and teacher professional development to facilitate the effective use of these materials with students can help build that bridge. The EET is an online resource that provides an easy way for educators to learn how to use Earth science datasets and data analysis tools to convey science concepts. Modules (called chapters) in the EET provide step-by-step instructions for accessing and analyzing these datasets within compelling case studies, and provide pedagogical information to help the educator use the data with their students. New EET chapters, featuring IPY data, can be developed through the use of an EET chapter template that standardizes the content and structure of the chapter. The initiation of new chapters can be facilitated through our Data in Education Workshops (previously DLESE Data Services Workshops, http://swiki.dlese.org/2006- dataservicesworkshop/). During these workshops IPY data providers, analysis tool specialists, IPY scientists, curriculum developers, and educators participate on teams of 5-6 members to create an outline of a new EET chapter featuring the IPY data and analysis tools represented on the team. New chapters will be completed by a curriculum developer following the workshop. Use of the IPY EET chapters will be facilitated by a range of professional development activities ranging from two 2-hour telecon-online workshops over the period of a month, to a year long professional development program that includes telecon-online workshops, a two-week summer workshop, follow-up online discussions and one-day meetings. In this paper we will discuss the EET and the spectrum of activities that can facilitate building a bridge between the IPY scientific community and future scientists and socially responsible citizens.

Commentary: Biochemistry and Molecular Biology Educators Launch National Network

ERIC Educational Resources Information Center

Bailey, Cheryl; Bell, Ellis; Johnson, Margaret; Mattos, Carla; Sears, Duane; White, Harold B.

2010-01-01

The American Society of Biochemistry and Molecular Biology (ASBMB) has launched an National Science Foundation (NSF)-funded 5 year project to support biochemistry and molecular biology educators learning what and how students learn. As a part of this initiative, hundreds of life scientists will plan and develop a rich central resource for…

Effective Integration of the World-Wide Web in Earth Science Education.

ERIC Educational Resources Information Center

Herbert, Bruce; Bednarz, Sarah; Boyd, Tom; Blake, Sally; Harder, Vicki; Sutter, Marilyn

The earth sciences is an evolving set of disciplines encompassing more than 30 specialties; however, earth scientists continue to be trained within the traditional disciplinary structure. Earth science education should focus not only on student acquisition and retention of factual knowledge, but also on the development of higher-order skills…

A Synchronous Distance Education Course for Non-Scientists Coordinated among Three Universities

ERIC Educational Resources Information Center

Smith, Tamara Floyd; Baah, David; Bradley, James; Sidler, Michelle; Hall, Rosine; Daughtrey, Terrell; Curtis, Christine

2010-01-01

A Synchronous Distance Education (SDE) course, jointly offered by Auburn University, Tuskegee University and Auburn University at Montgomery, introduced non-science majors to the concepts of nanoscience. Lectures originated from each of the three campuses during the semester, and video conferencing equipment allowed students at all three campuses…

"The Physics of Life," an Undergraduate General Education Biophysics Course

ERIC Educational Resources Information Center

Parthasarathy, Raghuveer

2015-01-01

Improving the scientific literacy of non-scientists is an important aim, both because of the ever-increasing impact of science on our lives and because understanding science enriches our experience of the natural world. One route to improving scientific literacy is via general education undergraduate courses--i.e. courses for students not majoring…

A Functional Conceptualization of Understanding Science in the News

ERIC Educational Resources Information Center

Anderson, Megan M.

2012-01-01

The idea that the public should have the capacity for understanding science in the news has been embraced by scientists, educators, and policymakers alike. An oft-cited goal of contemporary science education, in fact, is to enhance students' understanding of science in the news. But what exactly does it "mean" to understand science…

The Scientist-Practitioner: A Boulder Model for Education

ERIC Educational Resources Information Center

Dunn, Karee E.

2015-01-01

The purpose of the current work is to present a case for the need to train all graduate students in the field of education in quantitative methodology. The premise for this position is that practitioners like researchers benefit from such training. Through an understanding of research design and statistics, teachers, school leaders, counselors,…

Students and Scientists Connect with Nature in Uganda, East Africa

ERIC Educational Resources Information Center

Johnson-Pynn, Julie S.; Johnson, Laura R.; Kityo, Robert; Lugumya, Douglas

2014-01-01

We studied the impact of environmental education (EE) workshops on Ugandan youth's (N = 84) perceptions of their relationship with nature, self efficacy, and civic attitudes and skills. Two nature-related measures and two measures related to social competencies were administered before and after EE workshops that were designed to educate youth…

Perspectives, Partnerships, and Values in Science Education: A University and Public Elementary School Collaboration.

ERIC Educational Resources Information Center

Herwitz, Stanley R.; Guerra, Marion

1996-01-01

Describes a course teaching planetary science to elementary school students in collaboration with a university. Chronicles how a partnership between an elementary school teacher and a university-based research scientist effectively shaped the teacher's understanding of values and attitudes inherent in science education. Presents a model for…

Describing the Apprenticeship of Chemists through the Language of Faculty Scientists

ERIC Educational Resources Information Center

Skjold, Brandy Ann

2012-01-01

Attempts to bring authentic science into the K-16 classroom have led to the use of sociocultural theories of learning, particularly apprenticeship, to frame science education research. Science educators have brought apprenticeship to science classrooms and have brought students to research laboratories in order to gauge its benefits. The…

Improving the Students' Study Practices through the Principled Design of Research Probes

ERIC Educational Resources Information Center

Aleahmad, Turadig

2012-01-01

A key challenge of the learning sciences is moving research results into practice. Educators on the front lines perceive little value in the outputs of education research and demand more "usable knowledge". This work explores the potential instead of usable artifacts to translate knowledge into practice, adding scientists as stakeholders…

CosmoQuest: Training Students, Teachers and the Public to do NASA Science

NASA Astrophysics Data System (ADS)

Buxner, S.; Bracey, G.; Noel-Storr, J.; Murph, S.; Francis, M. R.; Strishock, L.; Cobb, W. H.; Lebofsky, L. A.; Jones, A. P.; Finkelstein, K.; Gay, P.

2016-12-01

Engaging individuals in science who have not been formally trained as research scientists can both capture a wider audiences in the process of science as well as crowdsource data analysis that gets more science done. CosmoQuest is a virtual research facility that leverages these benefits through citizen science projects that has community members to analyze NASA data that contributes to publishable science results. This is accomplished through an inviting experience that recruits members of the public (including students), meets their needs and motivations, and provides them the education they want so they can to be contributing members of the community. Each research project in CosmoQuest presents new training opportunities that are designed to meet the personal needs of the engaged individuals, while also leading to the production of high-quality data that meets the needs of the research teams. These educational opportunities extend into classrooms, where both teachers and students engage in analysis. Training for teachers is done through in-person and online professional development, and through conference workshops for both scientists and educators. Curricular products are available to support students' understanding of citizen science and how to engage in CosmoQuest projects. Professional development for all audiences is done through online tutorials and courses, with social media support. Our goal is to instill expertise in individuals not formally trained as research scientists. This allows them to work with and provide genuine scientific support to practicing experts in a community that benefits all stakeholders. Training focuses on increasing and supporting individuals' core content knowledge as well as building the specific skills necessary to engage in each project. These skills and knowledge are aligned with the 3-dimensional learning of the Next Generation Science Standards, and support lifelong learning opportunities for those in and out of school.

We Need You! The Importance of Scientist Involvement in Education and Public Outreach (E/PO)

NASA Astrophysics Data System (ADS)

Buxner, S.; Hsu, B. C.; Meinke, B. K.; Shipp, S. S.; Schwerin, T. G.; Peticolas, L. M.; Smith, D.; Dalton, H.

2013-12-01

Active engagement of scientists in education and public outreach (E/PO) activities is beneficial for scientists, classrooms, and the general public. Scientist visibility in the public arena is important to garner public support, whose tax dollars fund scientific programs. Scientists are important disseminators of current, accurate scientific knowledge. They also, perhaps more importantly, understand the nature and process of science and have the means of understanding and addressing many of the issues facing society. Research has shown that while the public is interested in science, not all members are necessarily scientifically literate; additionally there is evidence than many students are not prepared for, or choosing to participate in science careers. And yet, a scientifically engaged, literate, and supportive public is a necessary partner in addressing important global challenges of the future. E/PO is a wonderful opportunity for scientists to demonstrate that science is interesting, exciting, fun, challenging, and relevant to society. In doing so, they can transfer ownership of science to the public through a variety of vehicles by increasing access to scientific thought and discovery. Through partnerships with E/PO professionals, teachers, or journalists, scientists can improve their communication and teaching skills, whether in an E/PO setting or their higher education careers. Sharing with the public what scientists do is an effective way to engage people in the scientific process and to express scientists' enthusiasm for what they do. Scientist involvement in E/PO also shows the public that scientists are real people and provides important role models for the next generation of scientists. There are many opportunities to get involved in E/PO! Find information on EarthSpace, a national clearinghouse for higher education materials in Earth and space science through an abstract by Nicholas Gross, et al. Learn about NASA Science Mission Directorate (SMD)'s Scientist Speaker's Bureau in an abstract by Heather Dalton, et al. Discover the many resources and opportunities provided by NASA SMD's Science E/PO Forums in abstracts by Stephanie Shipp, et al. and Laura Peticolas, et al. Join the fun - get involved in E/PO!

Network Analysis of Beliefs About the Scientific Enterprise: A comparison of scientists, middle school science teachers and eighth-grade science students

NASA Astrophysics Data System (ADS)

Peters-Burton, Erin; Baynard, Liz R.

2013-11-01

An understanding of the scientific enterprise is useful because citizens need to make systematic, rational decisions about projects involving scientific endeavors and technology, and a clearer understanding of scientific epistemology is beneficial because it could encourage more public engagement with science. The purpose of this study was to capture beliefs for three groups, scientists, secondary science teachers, and eighth-grade science students, about the ways scientific knowledge is generated and validated. Open-ended questions were framed by formal scientific epistemology and dimensions of epistemology recognized in the field of educational psychology. The resulting statements were placed in a card sort and mapped in a network analysis to communicate interconnections among ideas. Maps analyzed with multidimensional scaling revealed robust connections among students and scientists but not among teachers. Student and teacher maps illustrated the strongest connections among ideas about experiments while scientist maps present more descriptive and well-rounded ideas about the scientific enterprise. The students' map was robust in terms of numbers of ideas, but were lacking in a hierarchical organization of ideas. The teachers' map displayed an alignment with the learning standards of the state, but not a broader view of science. The scientists map displayed a hierarchy of ideas with elaboration of equally valued statements connected to several foundational statements. Network analysis can be helpful in forwarding the study of views of the nature of science because of the technique's ability to capture verbatim statements from participants and to display the strength of connections among the statements.

Describing the apprenticeship of chemists through the language of faculty scientists

NASA Astrophysics Data System (ADS)

Skjold, Brandy Ann

Attempts to bring authentic science into the K-16 classroom have led to the use of sociocultural theories of learning, particularly apprenticeship, to frame science education research. Science educators have brought apprenticeship to science classrooms and have brought students to research laboratories in order to gauge its benefits. The assumption is that these learning opportunities are representative of the actual apprenticeship of scientists. However, there have been no attempts in the literature to describe the apprenticeship of scientists using apprenticeship theory. Understanding what science apprenticeship looks like is a critical component of translating this experience into the classroom. This study sought to describe and analyze the apprenticeship of chemists through the talk of faculty scientists. It used Lave and Wenger’s (1991) theory of Legitimate Peripheral Participation as its framework, concentrating on describing the roles of the participants, the environment and the tasks in the apprenticeship, as per Barab, Squire and Dueber (2000). A total of nine chemistry faculty and teaching assistants were observed across 11 settings representing a range of learning experiences from introductory chemistry lectures to research laboratories. All settings were videotaped, focusing on the instructor. About 89 hours of video was taken, along with observer field notes. All videos were transcribed and transcriptions and field notes were analyzed qualitatively as a broad level discourse analysis. Findings suggest that learners are expected to know basic chemistry content and how to use basic research equipment before entering the research lab. These are taught extensively in classroom settings. However, students are also required to know how to use the literature base to inform their own research, though they were rarely exposed to this in the classrooms. In all settings, conflicts occurred when student under or over-estimated their role in the learning environment. While faculty moved effortlessly between settings, students had difficulty adjusting to new roles in different settings. The findings suggest that one beneficial way of bringing apprenticeship into the classroom, would be to expose students to scientific literature early, emphasizing the community of practice and the roles that learners, faculty and scientists play within it.

Integrating the history of science into a middle school science curriculum

NASA Astrophysics Data System (ADS)

Huybrechts, Jeanne Marie

This study examined the effect of incorporating the history of science into a middle school physical science curriculum on student attitudes toward science and the work of scientists. While there is wide support for including some science history in middle school science lessons within both the science and science-education communities, there is little curriculum designed to meet that objective. A series of five lessons was written specifically for the study. Each lesson included a brief biography of a scientist whose work was of historical significance, and a set of directions for duplicating one or more of the experiments done by that scientist. A thirty-question, Likert scale survey of the attitudes of middle school students toward science and the work of scientists was also written for this study. The survey was administered to two groups of students in a single middle school: One group---the experimental group---subsequently used the science history curriculum; the second (control) group did not. The same attitude survey was readministered to both groups of students after study of the science-history curriculum was completed. The results of the study indicate that there was no statistically significant difference between the pretest and posttest scores of either the experimental or control group students. Further analysis was done to determine whether there were differences between the pretest and posttest scores of boys and girls, or between "regular" or "honors" students. In both cases no statistically significant difference was found.

Business involvement in science education

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

Winter, P.

1995-12-31

Science and math education in grades K through 12 directly affects America`s ability to meet tomorrow`s challenges. If America is to stay competitive in the world, we will need highly qualified scientists and engineers in industry and government and at universities. Jobs of the future will require greater technical and mathematical literacy than jobs of the past. Our goal is both to improve the quality of science education and to encourage more students to pursue science careers. General Atomics, a privately held research and development company, has joined the growing list of businesses that are committed to helping educators preparemore » students to meet these challenges.« less

Teaching graduate students The Art of Being a Scientist

NASA Astrophysics Data System (ADS)

Snieder, Roel

2011-03-01

Graduate education in the classroom traditionally focuses on disciplinary topics, with non-disciplinary skills only marginally discussed, if at all, between graduate student and adviser. Given the wide range of advisers with different types and quality of communication skill (or lack thereof), the professional coaching delivered to students often is restricted to just the technical aspects of research. Yet graduate students have a great need to receive professional training aimed at, among other things, helping their graduate career be more efficient, less frustrating and less needlessly time-consuming. We have addressed this gap in graduate education by developing the one-credit course ``The Art of Being a Scientist.'' This course covers a diverse range of topics of importance to being an effective and creative researcher. Topics covered include the following: What is science? Choosing a research topic, department, and adviser. The adviser and thesis committee. Making a work plan. Setting goals. Ethics of research. Using the scientific literature. Perfecting oral and written communication. Publishing papers and writing proposals. Managing time effectively. Planning a scientific career. Applying for jobs in academia or industry. In evaluations of the course, students invariably comment that they could have avoided significant problems in their graduate study and saved valuable time if they would have taken the course earlier on. This is an indication that the course not only useful for students, but also that it is best taken early in a their graduate career. The material covered in the course is captured in the book ``The Art of Being a Scientist: A Guide for Graduate Students and Their Mentors,'' published by Cambridge University Press; more information can be found at: www.mines.edu/~rsnieder/Art_of_Science.html From this website one can download a description of the curriculum used in the class, including homework exercises. Currently we are expanding of professional education by offering more lectures and workshops in order to better prepare graduate students for a career in science. Roel Snieder, Tom Boyd, and Ken Larner, Center for Wave Phenomena and Office of the Graduate School, Colorado School of Mines.

Flying the Infrared Skies: An Authentic SOFIA Educator Experience

NASA Astrophysics Data System (ADS)

Manning, J. G.

2015-11-01

The NASA/DLR Stratospheric Observatory for Infrared Astronomy (SOFIA) flagship education effort is its Airborne Astronomy Ambassadors (AAA) program. The program flies teams of teachers on SOFIA research flights as part of an educator professional development effort enabling these teachers to experience first-hand the workings of the airborne observatory, to interact with scientists and technologists, to observe research in progress and how scientists use technology—all in support of national STEM goals. The presenter will share his own experience as an EPO escort on a recent SOFIA flight including two educator teams, providing a first-hand account of how an “authentic” science experience can exploit unique NASA assets to improve science teaching, inspire students, inform local communities, and contribute to the elevation of public science literacy.

The formation of science choices in secondary school

NASA Astrophysics Data System (ADS)

Cleaves, Anna

2005-04-01

In this paper I examine the formation of post-16 choices over 3 years among higher achieving students with respect to enrolment in post-compulsory science courses. Transcripts from four interviews carried out over 3 years with 72 secondary school students were qualitatively analysed. Students were found to shape their choices for science in a variety of ways across time. The situation regarding science choices hinges on far more dynamic considerations than the stereotypical image of the potential advanced science student, committed to becoming a scientist from an early age. There is an interplay of self-perception with respect to science, occupational images of working scientists, relationship with significant adults and perceptions of school science The findings are informative for science educators and for career guidance professionals who may need to take into account the complexity of young people's choices.

Sharing Polar Science with Secondary Students: Polartrec and Beyond

NASA Astrophysics Data System (ADS)

Herrmann, N. E.

2014-12-01

This session will provide a variety of resources and lesson ideas for educators interested in effectively communicating polar science. Ms. Herrmann will share evidence of the direct impacts on secondary students that resulted from her collaboration with polar scientists in both the Arctic and Antarctic. Ms. Herrmann's interest in polar science began in 2009, when she worked as a field assistant in Kangerlussuaq, Greenland for scientists examining the effects of climate change on caribou. In 2011, she was selected to participate in PolarTREC (Teachers and Researchers Exploring and Collaborating), a professional development program for teachers and researchers, funded by NSF and coordinated by the Arctic Research Consortium of the United States (ARCUS). The opportunity provides teachers opportunities to collaborate with scientists and to share real world science with students. Ms. Herrmann will discuss her experience working with researchers at Palmer Station, Antarctica and how it led to her continued professional development with the Palmer Station Research Experience for Teachers (RET) program and with Polar Eduators (PEI), including a recent Master Class she presented with Dr. Richard Alley. She will also discuss her development of a program called Polar Ambassadors, in which older students become mentors to younger students in the field of polar science.

Comparing Active Game-Playing Scores and Academic Performances of Elementary School Students

ERIC Educational Resources Information Center

Kert, Serhat Bahadir; Köskeroglu Büyükimdat, Meryem; Uzun, Ahmet; Çayiroglu, Beytullah

2017-01-01

In the educational sciences, many discussions on the use of computer games occur. Most of the scientists believe that traditional computer games are time-consuming software and that game-playing activities negatively affect students' academic performance. In this study, the accuracy of this general opinion was examined by focusing on the real…

Radon Measurement Laboratories. An Educational Experience Based on School and University Cooperation

ERIC Educational Resources Information Center

De Cicco, F.; Balzano, E.; Limata, B. N.; Masullo, M. R.; Quarto, M.; Roca, V.; Sabbarese, C.; Pugliese, M.

2017-01-01

There is a growing interest in engaging students and the general public about the meaning and objectives of doing science. When it is possible students can learn by actively engaging in the practices of science, conducting investigations, sharing ideas with their peers, teachers and scientists, learning to work with measuring apparatuses, to…

Graduation, Graduate School Attendance, and Investments in College Training.

ERIC Educational Resources Information Center

Perl, Lewis J.

It has often been suggested by economists and other social scientists that the educational system may conveniently be viewed as a production process. The primary output of this process is an increase in the student's stock of knowledge and skill, and the inputs to the process including the student's time (the productivity of which depends upon a…

Understanding the Greenhouse Effect by Embodiment--Analysing and Using Students' and Scientists' Conceptual Resources

ERIC Educational Resources Information Center

Niebert, Kai; Gropengießer, Harald

2014-01-01

Over the last 20 years, science education studies have reported that there are very different understandings among students of science regarding the key aspects of climate change. We used the cognitive linguistic framework of experientialism to shed new light on this valuable pool of studies to identify the conceptual resources of understanding…

The Control of Ventilation during Exercise: A Lesson in Critical Thinking

ERIC Educational Resources Information Center

Bruce, Richard M.

2017-01-01

Learning the basic competencies of critical thinking are very important in the education of any young scientist, and teachers must be prepared to help students develop a valuable set of analytic tools. In my experience, this is best achieved by encouraging students to study areas with little scientific consensus, such as the control mechanisms of…

Intending to Stay: Images of Scientists, Attitudes Toward Women, and Gender as Influences on Persistence among Science and Engineering Majors

NASA Astrophysics Data System (ADS)

Wyer, Mary

Contemporary research on gender and persistence in undergraduate education in science and engineering has routinely focused on why students leave their majors rather than asking why students stay. This study compared three common ways of measuring persistence-commitment to major, degree aspirations, and commitment to a science or engineering career-and emphasized factors that would encourage students to persist, including positive images of scientists and engineers, positive attitudes toward gender equity in science and engineering, and positive classroom experiences. A survey was administered in classrooms to a total of 285 female and male students enrolled in two required courses for majors. The results indicate that the different measures of persistence were sensitive to different influences but that students' gender did not interact with their images, attitudes, and experiences in predicted ways. The study concludes that an individual student's gender may be a more important factor in explaining why some female students leave their science and engineering majors than in explaining why others stay.

Can medical schools teach high school students to be scientists?

PubMed

Rosenbaum, James T; Martin, Tammy M; Farris, Kendra H; Rosenbaum, Richard B; Neuwelt, Edward A

2007-07-01

The preeminence of science in the United States is endangered for multiple reasons, including mediocre achievement in science education by secondary school students. A group of scientists at Oregon Health and Science University has established a class to teach the process of scientific inquiry to local high school students. Prominent aspects of the class include pairing of the student with a mentor; use of a journal club format; preparation of a referenced, hypothesis driven research proposal; and a "hands-on" laboratory experience. A survey of our graduates found that 73% were planning careers in health or science. In comparison to conventional science classes, including chemistry, biology, and algebra, our students were 7 times more likely to rank the scientific inquiry class as influencing career or life choices. Medical schools should make research opportunities widely available to teenagers because this experience dramatically affects one's attitude toward science and the likelihood that a student will pursue a career in science or medicine. A federal initiative could facilitate student opportunities to pursue research.

I Want to Be a Scientist/A Teacher: Students' Perceptions of Career Decision-Making in Gender-Typed, Non-Traditional Areas of Work

ERIC Educational Resources Information Center

Buschor, Christine Bieri; Kappler, Christa; Keck Frei, Andrea; Berweger, Simone

2014-01-01

The study examines the career decision-making of Swiss academic high school students opting for a career in a non-traditional, gender-typed area of work during the transition to higher education. Based on a longitudinal study, a qualitative study with 11 female students in Science, Technology, Engineering and Mathematics (STEM) and 13 male student…

Educational and Community Outreach Efforts by the United States Polar Rock Repository during the International Polar Year

NASA Astrophysics Data System (ADS)

Grunow, A.; Codispoti, J. E.

2010-12-01

The US Polar Rock Repository (USPRR) houses more than 19,000 rock samples from polar regions and these samples are made available to the scientific, educational and museum community. The USPRR has been active in promoting polar earth science to educational and community groups. During the past year, outreach efforts reached over 12,000 people. The USPRR outreach involve tours of the facility, school presentations, online laboratory exercises, working with the Columbus Metro Parks, teaching at summer camps, teaching special geology field assignments at the middle school level, as well as offering an ‘Antarctic Rock Box’ that contains representative samples of the three types of rocks, minerals, fossils, and books and activities about geology and Antarctica. The rock box activities have been designed and reviewed by educators and scientists to use as an educational supplement to the Earth Science course of study. The activities have been designed around the Academic Content Standards: k-12 Science manual published by the Ohio Department of Education to ensure that the activities and topics are focused on those mandated by the state of Ohio. The USPRR website has a Virtual Web Antarctic Expedition with many activities for Middle to High School age students. The students learn about how to plan a field season, safety techniques, how to make a remote field camp, identify what equipment is needed, learn about the different transportation choices, weather issues, understanding GPS, etc. Educational and community networks have been built in part, by directly contacting individuals at an institution and partnering with them on educational outreach. The institutions have been very interested in doing this because it brings scientists to the classroom and to the public. This type of outreach has also served as an opening for children to consider possible career choices in science that they may not have considered before. In many of the presentations, a female geologist has been the presenter, and this shows children that anyone can be a scientist/geologist. The most effective way to reach future scientists is to have fun, hands-on, energetic activities. Some children do well with classroom discussion and learning, but many do not. Following discussion of a polar earth science topic, we do hands-on activities to help students understand what has just been discussed. Projects in which the students make their own observations and conclusions have been very successful. One of the most useful things that the USPRR has done is to provide educators with activities to help drive the polar earth science ideas home. It is also helpful to give teachers concise background information to each activity and then provide reliable online resources if they should want more detailed information. In order to continue to improve the USPRR educational resources, questionnaires and/or evaluation forms are given to the participants. The evaluation replies have been especially helpful in reformatting our educational Antarctic rock boxes.

Forging School-Scientist Partnerships: A Case of Easier Said than Done?

NASA Astrophysics Data System (ADS)

Falloon, Garry

2013-12-01

Since the early 1980s, a number of initiatives have been undertaken worldwide which have involved scientists and teachers working together in projects designed to support the science learning of students. Many of these have attempted to establish school-scientist partnerships. In these, scientists, teachers, and students formed teams engaged in mutually beneficial science-based activities founded on principles such as equal recognition and input, and shared vision, responsibility and risk. This article uses two partnership programmes run by a New Zealand Science Research Institute, to illustrate the challenges faced by scientists and teachers as they attempted to forge meaningful and effective partnerships. It argues that achieving the theorised position of a shared partnership space at the intersection of the worlds of scientists and teachers is problematic, and that scientists must instead be prepared to penetrate deeply into the world of the classroom when undertaking any such interactions. Findings indicate epistemological differences, curriculum and school systems and issues, and teacher efficacy and science knowledge significantly affect the process of partnership formation. Furthermore, it is argued that a re-thinking of partnerships is needed to reflect present economic and education environments, which are very different to those in which they were originally conceived nearly 30 years ago. It suggests that technology has an important role to play in future partnership interactions.

KSC-03pd0516

NASA Image and Video Library

2003-02-19

KENNEDY SPACE CENTER, FLA. - At NASA's Family & Community Mars Exploration Day, held in Cape Canaveral, Fla., James Garvin, lead scientist for the Mars Exploration Program, talks to students about the Mars Exploration Rover. Garvin is standing next to a replica of the Rover. The event informed students and the general public about Florida's key role as NASA's "Gateway to Mars" and offered an opportunity to meet with scientists, engineers, educators and others working Mars exploration missions. The Mars Exploration Rovers are being prepared for launch this spring aboard Boeing Delta II rockets from the Cape Canaveral Air Force Station. They will land on Mars and start exploring in January 2004.

KSC-03PD-0516

NASA Technical Reports Server (NTRS)

2003-01-01

KENNEDY SPACE CENTER, FLA. - At NASA's Family & Community Mars Exploration Day, held in Cape Canaveral, Fla., James Garvin, lead scientist for the Mars Exploration Program, talks to students about the Mars Exploration Rover. Garvin is standing next to a replica of the Rover. The event informed students and the general public about Florida's key role as NASA's 'Gateway to Mars' and offered an opportunity to meet with scientists, engineers, educators and others working Mars exploration missions. The Mars Exploration Rovers are being prepared for launch this spring aboard Boeing Delta II rockets from the Cape Canaveral Air Force Station. They will land on Mars and start exploring in January 2004.

Internships and UNAVCO: Training the Future Geoscience Workforce Through the NSF GAGE Facility

NASA Astrophysics Data System (ADS)

Morris, A. R.; MacPherson-Krutsky, C. C.; Charlevoix, D. J.; Bartel, B. A.

2015-12-01

Facilities are uniquely positioned to both serve a broad, national audience and provide unique workforce experience to students and recent graduates. Intentional efforts dedicated to broadening participation in the future geoscience workforce at the NSF GAGE (Geodesy Advancing Geosciences and EarthScope) Facility operated by UNAVCO, are designed to meet the needs of the next generation of students and professionals. As a university-governed consortium facilitating research and education in the geosciences, UNAVCO is well-situated to both prepare students for geoscience technical careers and advanced research positions. Since 1998, UNAVCO has offered over 165 student assistant or intern positions including engineering, data services, education and outreach, and business support. UNAVCO offers three formal programs: the UNAVCO Student Internship Program (USIP), Research Experiences in Solid Earth Science for Students (RESESS), and the Geo-Launchpad (GLP) internship program. Interns range from community college students up through graduate students and recent Masters graduates. USIP interns gain real-world work experience in a professional setting, collaborate with teams toward a common mission, and contribute their knowledge, skills, and abilities to the UNAVCO community. RESESS interns conduct authentic research with a scientist in the Front Range area as well as participate in a structured professional development series. GLP students are in their first 2 years of higher education and work alongside UNAVCO technical staff gaining valuable work experience and insight into the logistics of supporting scientific research. UNAVCO's efforts in preparing the next generation of scientists largely focuses on increasing diversity in the geosciences, whether continuing academic studies or moving into the workforce. To date, well over half of our interns and student assistants come from backgrounds historically underrepresented in the geosciences. Over 80% of former interns continue to pursue careers or education in the geosciences. This presentation will highlight elements of the programs that can be easily replicated in other facilities as well as activities that may be incorporated into university-based experiences.

Surface Ozone Measured at GLOBE Schools in the Czech Republic: A Demonstration of the Importance of Student Contribution to the Larger Science Picture

NASA Technical Reports Server (NTRS)

Pippin, Margaret R.; Creilson, John K.; Henderson, Bryana L.; Ladd, Irene H.; Fishman, Jack; Votapkova, Dana; Krpcova, Ilona

2008-01-01

GLOBE (Global Learning and Observations to Benefit the Environment) is a worldwide hands-on, primary and secondary school-based education and science program, developed to give students a chance to perform real science by making measurements, analyzing data, and participating in research in collaboration with scientists. As part of the GLOBE Surface Ozone Protocol and with the assistance of the TEREZA Association in the Czech Republic, schools in the Czech Republic have been making and reporting daily measurements of surface ozone and surface meteorological data since 2001. Using a hand-held ozone monitor developed for GLOBE, students at several Czech schools have generated multiyear data records of surface ozone from 2001 to 2005. Analysis of the data shows surface ozone levels were anomalously high during the summer of 2003 relative to other summers. These findings are consistent with measurements by the European Environment Agency that highlights the summer of 2003 as having exceptionally long-lasting and spatially extensive episodes of high surface ozone, especially during the first half of August. Further analysis of the summer s prevailing meteorology shows not only that it was one of the hottest on record, a finding also seen in the student data, but the conditions for production of ozone were ideal. Findings such as these increase student, teacher, and scientist confidence in the utility of the GLOBE data for engaging budding scientists in the collection, analysis, and eventual interpretation of the data for inquiry-based education.

SoTRE's Speak Up: Students Share the Benefits of Teacher Researcher Experiences

NASA Astrophysics Data System (ADS)

Eubanks, E.; Allen, S.; Farmer, S.; Jones, K.

2016-12-01

Being Students of Teacher Researcher Experiences (SoTRE) gives students special advantages that most students do not get. Teachers Elizabeth Eubanks and Steve Allen share their knowledge gained via partnerships with Teacher Researcher Experiences (TRE's) such as the National Oceanographic and Atmospheric Administration Teacher at Sea program (NOAA- TAS), Polar TREC (Teachers and Researchers & Exploring & Collaboration), National Science Foundation (NSF) funded researchers, (EARTH) Education and Research: Testing Hypothesis, the RJ Dunlap Marine Conservation Program, C-DEBI (Center for Dark Energy Biosphere Investigations and (STARS) Sending Teachers Aboard Research Ships, The Maury Project and Mate. Students gain special privileges such as understanding unique research ideas, tracking tagged sharks, following daily journals written on location, taking part in cross-continental experiments, tracking real time data, exploring current research via posters or visiting universities. Furthermore, contacts made by a TRE give students an added set of resources. When doing experiments for class or advancing their education or career goals Eubanks and Allen help students connect with scientists. Many students have felt so strongly about the TRE relationship that they have presented at several local and international science conferences. Their message is to encourage scientists to partner with teachers. The benefits of participation in such conferences have included abstract writing and submission, travel, poster creation, oral presentation, networking and personal research presentation, all tools that they will carry with them for a lifetime.

Lab Aliens, Legendary Fossils, and Deadly Science Potions: Views of Science and Scientists from Fifth Graders in a Free-Choice Creative Writing Program

NASA Astrophysics Data System (ADS)

Hellman, Leslie G.

This qualitative study uses children's writing to explore the divide between a conception of Science as a humanistic discipline reliant on creativity, ingenuity and out of the box thinking and a persistent public perception of science and scientists as rigid and methodical. Artifacts reviewed were 506 scripts written during 2014 and 2016 by 5th graders participating in an out-of classroom, mentor supported, free-choice 10-week arts and literacy initiative. 47% (237) of these scripts were found to contain content relating to Science, Scientists, Science Education and the Nature of Science. These 237 scripts were coded for themes; characteristics of named scientist characters were tracked and analyzed. Findings included NOS understandings being expressed by representation of Science and Engineering Practices; Ingenuity being primarily linked to Engineering tasks; common portrayals of science as magical or scientists as villains; and a persistence in negative stereotypes of scientists, including a lack of gender equity amongst the named scientist characters. Findings suggest that representations of scientists in popular culture highly influence the portrayals of scientists constructed by the students. Recommendations to teachers include encouraging explicit consideration of big-picture NOS concepts such as ethics during elementary school and encouraging the replacement of documentary or educational shows with more engaging fictional media.

The Nautilus Exploration Program: Utilizing Live Ocean Exploration as a Platform for STEM Education and Outreach

NASA Astrophysics Data System (ADS)

Fundis, A.; Cook, M.; Sutton, K.; Garson, S.; Poulton, S.; Munro, S.

2016-02-01

By sparking interest in scientific inquiry and engineering design at a young age through exposure to ocean exploration and innovative technologies, and building on that interest throughout students' educational careers, the Ocean Exploration Trust (OET) aims to motivate more students to be lifelong learners and pursue careers in STEM fields. Utilizing research conducted aboard Exploration Vessel Nautilus, the ship's associated technologies, and shore-based facilities at the University of Rhode Island — including the Graduate School of Oceanography and the Inner Space Center — we guide students to early career professionals through a series of educational programs focused on STEM disciplines and vocational skills. OET also raises public awareness of ocean exploration and research through a growing online presence, live streaming video, and interactions with the team aboard the ship 24 hours a day via the Nautilus Live website (www.nautiluslive.org). Annually, our outreach efforts bring research launched from Nautilus to tens of millions worldwide and allow the public, students, and scientists to participate in expeditions virtually from shore. We share the Nautilus Exploration Program's strategies, successes, and lessons learned for a variety of our education and outreach efforts including: 1) enabling global audiences access to live ocean exploration online and via social media; 2) engaging onshore audiences in live and interactive conversations with scientists and engineers on board; 3) engaging young K-12 learners in current oceanographic research via newly developed lessons and curricula; 4) onshore and offshore professional development opportunities for formal and informal educators; 5) programs and authentic research opportunities for high school, undergraduate, and graduate students onshore and aboard Nautilus; and 6) collaborative opportunities for early career and seasoned researchers to participate virtually in telepresence-enabled, interdisciplinary expeditions.

Argumentation and indigenous knowledge: socio-historical influences in contextualizing an argumentation model in South African schools

NASA Astrophysics Data System (ADS)

Gallard Martínez, Alejandro J.

2011-09-01

This forum considers argumentation as a means of science teaching in South African schools, through the integration of indigenous knowledge (IK). It addresses issues raised in Mariana G. Hewson and Meshach B. Ogunniyi's paper entitled: Argumentation-teaching as a method to introduce indigenous knowledge into science classrooms: opportunities and challenges. As well as Peter Easton's: Hawks and baby chickens: cultivating the sources of indigenous science education; and, Femi S. Otulaja, Ann Cameron and Audrey Msimanga's: Rethinking argumentation-teaching strategies and indigenous knowledge in South African science classrooms. The first topic addressed is that implementation of argumentation in the science classroom becomes a complex endeavor when the tensions between students' IK, the educational infrastructure (allowance for teacher professional development, etc.) and local belief systems are made explicit. Secondly, western styles of debate become mitigating factors because they do not always adequately translate to South African culture. For example, in many instances it is more culturally acceptable in South Africa to build consensus than to be confrontational. Thirdly, the tension between what is "authentic science" and what is not becomes an influencing factor when a tension is created between IK and western science. Finally, I argue that the thrust of argumentation is to set students up as "scientist-students" who will be considered through a deficit model by judging their habitus and cultural capital. Explicitly, a "scientist-student" is a student who has "learned," modeled and thoroughly assimilated the habits of western scientists, evidently—and who will be judged by and held accountable for their demonstration of explicit related behaviors in the science classroom. I propose that science teaching, to include argumentation, should consist of "listening carefully" (radical listening) to students and valuing their language, culture, and learning as a model for "science for all".

Teacher Preparation with GLOBE and NASA Assets

NASA Astrophysics Data System (ADS)

Czajkowski, K. P.; Templin, M.; Struble, J.; Mierzwiak, S.; Hedley, M. L.; Padgett, D.

2017-12-01

The GLOBE Program has been a working with teachers and students for over 20 years. Pre-service education students can be a target audience as well. Mission EARTH is a NASA funded project through the NASA Cooperative Agreement Notice (CAN) from the Science Mission Directorate. A goal of Mission EARTH is to improve student understanding of Earth System Science and to engage the next generation of scientists and global citizens. This presentation will discuss Weather and Climate courses offered at both the University of Toledo and Tennessee State University for pre-service education students. Students engaged in atmospheric observations through the GLOBE protocols and developed research projects to study El Nino. Undergraduate students helped K-12 students take GLOBE observations as well by partnering with in-service GLOBE teachers affiliated with these GLOBE partnerships.

Broadening the Participation of Native Americans in Earth Science

NASA Astrophysics Data System (ADS)

Bueno Watts, Nievita

Climate change is not a thing of the future. Indigenous people are being affected by climate changes now. Native American Earth scientists could help Native communities deal with both climate change and environmental pollution issues, but are noticeably lacking in Earth Science degree programs. The Earth Sciences produce the lowest percentage of minority scientists when compared with other science and engineering fields. Twenty semi-structured interviews were gathered from American Indian/ Alaska Native Earth Scientists and program directors who work directly with Native students to broaden participation in the field. Data was analyzed using qualitative methods and constant comparison analysis. Barriers Native students faced in this field are discussed, as well as supports which go the furthest in assisting achievement of higher education goals. Program directors give insight into building pathways and programs to encourage Native student participation and success in Earth Science degree programs. Factors which impede obtaining a college degree include financial barriers, pressures from familial obligations, and health issues. Factors which impede the decision to study Earth Science include unfamiliarity with geoscience as a field of study and career choice, the uninviting nature of Earth Science as a profession, and curriculum that is irrelevant to the practical needs of Native communities or courses which are inaccessible geographically. Factors which impede progress that are embedded in Earth Science programs include educational preparation, academic information and counseling and the prevalence of a Western scientific perspective to the exclusion of all other perspectives. Intradepartmental relationships also pose barriers to the success of some students, particularly those who are non-traditional students (53%) or women (80%). Factors which support degree completion include financial assistance, mentors and mentoring, and research experiences. Earth scientists can begin broaden participation by engaging in community-inspired research, which stems from the needs of a community and is developed in collaboration with it. Designed to be useful in meeting the needs of the community, it should include using members of the community to help gather and analyze data. These community members could be students or potential students who might be persuaded to pursue an Earth Science degree.

Enhancing Science Education Instruction: A Mixed-Methods Study on University and Middle School Collaborations

NASA Astrophysics Data System (ADS)

Owen-Stone, Deborah S.

The purpose of this concurrent mixed methods study was to examine the collaborative relationship between scientists and science teachers and to incorporate and advocate scientific literacy based on past and current educational theories such as inquiry based teaching. The scope of this study included archived student standardized test scores, semi-structured interviews, and a Likert scale survey to include open-ended comments. The methodology was based on the guiding research question: To what extent and in what ways does the collaboration and inquiry methodology, with GTF and PT teams, serve toward contributing to a more comprehensive and nuanced understanding of this predicting relationship between student PASS scores, inquiry skills, and increased scientific literacy for GTF's, PT's, and students via an integrative mixed methods analysis? The data analysis considerations were derived from the qualitative data collected from the three GTF/PT teams by the use of recorded interviews and text answered survey comments. The quantitative data of archived student Palmetto Assessment of State Standards (PASS) scores on scientific literacy and inquiry tests and the Likert-scale portion of the survey were support data to the aforementioned qualitative data findings. Limitations of the study were (1) the population of only the GK-12 teachers and their students versus the inclusion of participants that did not experience the GK-12 Fellow partnerships within their classrooms, should they be considered as participants, (2) involved the researcher as a participant for two years of the program and objectivity remained through interpretation and well documented personal reflections and experiences to inform accuracy, and (3) cultural diversity contributed to the relationship formed between the research Fellow and science educator and communication and scientific language did form a barrier between the Fellow, educator, and student rapport within the classroom. This study's contribution benefits science education, scientists, university science education, and future collaborations. Key Terms: mixed methods, GK-12, scientific literacy, inquiry, collaboration.

Communication Skills for Conservation Professionals.

ERIC Educational Resources Information Center

Jacobson, Susan K.

This book provides in-depth guidance for students, scientists, managers, and professionals in achieving conservation goals through better communication. It introduces communication approaches--marketing and mass media, citizen participation, public information, environmental interpretation, and conservation education activities--and offers scores…

My school voyages with PERSEUS - PERSEUS@SCHOOL

NASA Astrophysics Data System (ADS)

Fermeli, Georgia; Papathanassiou, Evangelos; Papatheodorou, George; Streftaris, Nikos; Ioakeimidis, Christos

2014-05-01

PERSEUS@SCHOOL is an international environmental education thematic school network which is inspired and supported by the European research project PERSEUS (Policy Oriented Marine Environmental Research in Southern European Seas_http://www.perseus-net.eu) which is funded by EU FP7 Theme "Ocean of Tomorrow" and it is coordinating by the Hellenic Centre for Marine Research (HCMR). The overall scientific objectives of PERSEUS (FP7) research project are to identify the interacting patterns of natural and human-derived pressures on the Mediterranean and Black Seas, assess their impact on marine ecosystems and, using the objectives and principles of the Marine Strategy Framework Directive as a vehicle, to design an effective and innovative research governance framework based on solid scientific knowledge. This research governance framework will engage scientists, policy-makers and the public, thereby reaching a shared understanding and informed decision-making based on sound scientific knowledge. PERSEUS@SCHOOL network is coordinated by the Department of Environmental Education of the 1st Directorate of Secondary Education of Athens and aims to help and enhance environmental education, focusing on clean seas stewardship in schools. Educators along with marine scientists have a role in supporting and inspiring children to acquire the knowledge, skills and inspire their awareness to live and work as responsible and concerned citizens. For this purpose, the network has designed specific pedagogical activities for primary and secondary education - based on PERSEUS key thematic areas i.e. Marine biodiversity, Overfishing, Chemical Marine Pollution - Bioaccumulation - Health, Eutrophication in Marine Waters and Marine Litter. Complementary, two web-monitoring tools will be used by the network; the Jellyfish Spotting campaign and the Marine LitterWatch (MLW) app (Developed by EEA). A special emphasis is given to MLW app, as school students for first time will use it in order to test this new tool and to monitor beach marine litter in selected areas in Greece. The pedagogical activities of the network will give students an opportunity to explore similarities and differences between schools and nationalities, while simultaneously creating awareness of other young people's reality in a captivating way. PERSEUS@SCHOOL will allow students to use their imagination and knowledge provided by PERSEUS scientists, in order to think and act about the marine environment and its protection in an interactive, appealing and imaginative way. Finally, students will participate in a "true" expedition in the Aegean Sea, on the R/V AEGAEO of the Hellenic Centre for Marine Research (HCMR). The aim of this expedition is to involve students in marine scientific research and guide them to recognize the 'value' of the Mediterranean Sea and the threats and challenges it faces in the modern world. During this expedition, students will collaborate with marine scientists creating a powerful interactive learning experience, participate in experiments, interpret research findings, draw conclusions and voice their opinion for the "Oceans of tomorrow".

In the Footsteps of Roger Revelle: Seagoing Oceanography for Middle School Science

NASA Astrophysics Data System (ADS)

Brice, D.; Foley, S.; Knox, R. A.; Mauricio, P.

2007-12-01

Now in its fourth year, "In the Footsteps of Roger Revelle" (IFRR) is a middle school science education program that draws student interest, scientific content and coherence with National Science Standards from real-time research at sea in fields of physical science. As a successful collaboration involving Scripps Institution of Oceanography (SIO), Woods Hole Oceanographic Institution (WHOI), National Oceanic and Atmospheric Administration (NOAA), Office of Naval Research (ONR), National Science Foundation (NSF), San Diego County Office of Education (SDCOE), and San Marcos Middle School (SMMS), IFRR brings physical oceanography and related sciences to students at the San Marcos Middle School in real-time from research vessels at sea using SIO's HiSeasNet satellite communication system. With their science teacher on the ship as an education outreach specialist or ashore guiding students in their interactions with selected scientists at sea, students observe shipboard research being carried out live via videoconference, daily e-mails, interviews, digital whiteboard sessions, and web interaction. Students then research, design, develop, deploy, and field-test their own data-collecting physical oceanography instruments in their classroom. The online interactive curriculum encourages active inquiry with intellectually stimulating problem-solving, enabling students to gain critical insight and skill while investigating some of the most provocative questions of our time, and seeing scientists as role- models. Recent science test scores with IFRR students have shown significant increases in classes where this curriculum has been implemented as compared to other classes where the traditional curriculum has been used. IFRR has provided students in the San Diego area with a unique opportunity for learning about oceanographic research, which could inspire students to become oceanographers or at least scientifically literate citizens - a benefit for a country that depends increasingly on technically proficient personnel, and a benefit for society at large.

Soil Science Education for Primary and Secondary Students

NASA Astrophysics Data System (ADS)

Sparrow, Elena; Yoshikawa, Kenji; Kopplin, Martha

2013-04-01

Soils is one of the science investigation areas in the Global learning and Observations to Benefit the Environment (GLOBE), an international science and education program (112 countries) that teaches primary and secondary students to learn science by doing science. For each area of investigation GLOBE provides background information, measurement protocols and learning activities compiled as a chapter in the GLOBE Teacher's Guide. Also provided are data sheets and field guides to assist in the accurate collection of data as well as suggestions of scientific instruments and calibration methods. Teachers learn GLOBE scientific measurement protocols at professional development workshops led by scientists and educators, who then engage their students in soil studies that also contribute to ongoing science investigations. Students enter their data on the GLOBE website and can access their data as well as other data contributed by students from other parts of the world. Soil characterization measurements carried out in the field include site description, horizon depths, soil structure, soil color, soil consistence, soil texture, roots, rocks and carbonates. Other field measurements are soil temperature and soil moisture monitoring while the following measurements are carried out in the classroom or laboratory: gravimetric soil moisture, bulk density, particle density, particle size distribution, pH and soil fertility (nitrogen, phosphorus and potassium). Learning activities provide support for preparing students to do the measurements and for better understanding of science concepts. Many countries in GLOBE have adopted standards for education including science education with commonalities among them. For the Teacher's Guide, the National Science Education Standards published by the US National Academy of Sciences, selected additional content standards that GLOBE scientists and educators feel are appropriate and the National Geography Standards prepared by the (US) National Education Standards Project, are being used. Educational objectives for students include gaining scientific inquiry abilities in addition to understanding scientific concepts. The Soils chapter also includes some suggestions for managing students in the field and classroom. A new protocol has also been developed by the Seasons and Biomes project, one of the GLOBE earth system science projects. Active Layer monitoring uses a Frost Tube that measures when and how deeply soil freezes and is currently being used in more than 200 sites in Alaska. Teachers have successfully implemented soil studies in their curriculum and have used it to teach about the science process.

Ocean Literacy: Tools for Scientists and Educators to use in the Development of Education and Outreach Programs About the Ocean

NASA Astrophysics Data System (ADS)

Strang, C.; Lemus, J.; Schoedinger, S.

2006-12-01

Ocean sciences were idiosyncratically left out of the National Science Education Standards and most state standards, resulting in a decline in the public's attention to ocean issues. Concepts about the ocean are hardly taught in K-12 schools, and hardly appear in K-12 curriculum materials, textbooks, assessments or standards. NGS, COSEE, NMEA, NOAA, the US Commission on Ocean Policy, the Pew Ocean Commission have all urgently called for inclusion of the ocean in science standards as a means to increase ocean literacy nationwide. There has never been consensus, however, about what ocean literacy is or what concepts should be included in future standards. Scientists interested in education and outreach activities have not had a framework to guide them in prioritizing the content they present or in determining how that content fits into the context of what K-12 students and the public need to know about science in general. In 2004, an on-line workshop on Ocean Literacy Through Science Standards began the process of developing consensus about what that framework should include. Approximately 100 ocean scientists and educators participated in the workshop, followed by a series of meetings and extensive review by leading scientists, resulting in a series of draft documents and statements. The importance of community-wide involvement and consensus was reinforced through circulation of the draft documents for public comment April -May, 2005. The community agreed on an Ocean Literacy definition, tagline, seven ocean principles, 44 concepts and a matrix aligning the concepts to the National Science Education Standards (NSES). The elements are described in more detail in the final Ocean Literacy brochure. Broad ownership of the resulting documents is a tribute to the inclusiveness of the process used to develop them. The emerging consensus on Ocean Literacy has become an instrument for change, and has served as an important tool guiding the ocean sciences education efforts of scientists, educators, and most importantly, has provided a common language for scientists and educators working together. In this past year, a similar community-wide effort has been mounted to develop an "Ocean Literacy Scope and Sequence" to serve as a critical companion to "Ocean Literacy: The Essential Principles of Ocean Sciences Grades K-12." The Scope and Sequence shows how the principles and concepts develop and build in logical and developmentally sound learning progressions across grade spans K-12. This document will provide further guidance to teachers, curriculum developers, textbook writers, and ocean scientists, as to what concepts about the ocean are appropriate to introduce at various grade spans. It will show the relationship between the new discoveries of cutting edge science and the basic science concepts on which they are built and which students are accountable to understand. Those concerned about science education and about the future health of the ocean must be poised to influence the development of science standards by local educational agencies, state departments of education and professional societies and associations. In order to be effective, we must have tools, products, documents, web sites that contain agreed upon science content and processes related to the ocean.

Effective Models for Scientists Engaging in Meaningful Education and Outreach

NASA Astrophysics Data System (ADS)

Noel-Storr, Jacob; Gurule, Isaiah; InsightSTEM Teacher-Scientist-Communicator-Learner Team

2017-01-01

We present a central paradigm, extending the model of "Teacher-Scientist" partnerships towards a new philosophy of "Scientist-Instructor-Learner-Communicator" Partnerships. In this paradigm modes of, and expertise in, communication, and the learners themselves, are held is as high status as the experts and teachers in the learning setting.We present three distinctive models that rest on this paradigm in different educational settings. First a model in which scientists and teachers work together with a communications-related specialist to design and develop new science exploration tools for the classroom, and gather feedback from learners. Secondly, we present a model which involves an ongoing joint professional development program helping scientists and teachers to be co-communicators of knowledge exploration to their specific audience of learners. And thirdly a model in which scientists remotely support classroom research based on online data, while the teachers and their students learn to become effective communicators of their genuine scientific results.This work was funded in part by the American Association for the Advancement of Science, and by NASA awards NNX16AC68A and NNX16AJ21G. All opinions are those of the authors.

Effective Models for Scientists Engaging in Meaningful Education and Outreach

NASA Astrophysics Data System (ADS)

Noel-Storr, Jacob; InsightSTEM SILC Partnership Team

2016-10-01

We present a central paradigm, extending the model of "Teacher-Scientist" partnerships towards a new philosophy of "Scientist-Instructor-Learner-Communicator" Partnerships. In this paradigm modes of, and expertise in, communication, and the learners themselves, are held is as high status as the experts and teachers in the learning setting.We present three distinctive models that rest on this paradigm in different educational settings. First a model in which scientists and teachers work together with a communications-related specialist to design and develop new science exploration tools for the classroom, and gather feedback from learners. Secondly, we present a model which involves an ongoing joint professional development program helping scientists and teachers to be co-communicators of knowledge exploration to their specific audience of learners. And thirdly a model in which scientists remotely support classroom research based on online data, while the teachers and their students learn to become effective communicators of their genuine scientific results.This work was funded in part by the American Association for the Advancement of Science, and by NASA awards NNX16AC68A and NNX16AJ21G. All opinions are those of the authors.

GLOBE Cornerstones: Advancing Student Research Worldwide through Virtual and Regional Symposia

NASA Astrophysics Data System (ADS)

Bourgeault, J.; Malmberg, J. S.; Murphy, T.; Darche, S.; Ruscher, P.; Jabot, M.; Odell, M. R. L.; Kennedy, T.

2016-12-01

The GLOBE Program, an international science and education program, encourages students from around the world to participate in authentic scientific research of the Earth system. Students use scientific protocols to explore their local environments, compare their findings with other GLOBE schools both in the U.S. and in other participating countries, and then share their findings via the GLOBE.gov website. In order to facilitate this scientific communication, GLOBE held an international virtual science fair in 2016. The science fair included 105 research projects submitted from GLOBE students in various countries, 37 mentoring scientists, and 24 judges. Mentors and judges were members of the GLOBE International STEM Professionals Network and located around the world. On a national level, NSF funded six face-to-face U.S. regional student research symposia where 164 students presented 67 research projects to scientists for review. The 1.5 day events included student activities, teacher professional development, tours of NASA centers, and opportunities for students to engage with scientists to discover both traditional and non-traditional STEM career pathways. To support teachers, the leadership team offered and archived webinars on science practices; from field investigation basics to creating a poster and GLOBE partners provided guidance along the way. This presentation will include the framework for the regional and international science symposia , the scoring rubrics and evaluation, recruitment of judges and mentors, and lessons learned.

In the Footsteps of Roger Revelle: a Partnership between SIO, ONR and Middle School Science Students

NASA Astrophysics Data System (ADS)

Brice, D.; Appelgate, T. B.; Foley, S.; Knox, R. A.; Mauricio, P.

2010-12-01

Now in its seventh year, “In the Footsteps of Roger Revelle” (IFRR) is a middle school science education program that draws student interest, scientific content and coherence with National Science Standards from real-time research at sea in fields of physical science. As a successful collaboration involving Scripps Institution of Oceanography (SIO), National Science Foundation (NSF),Office of Naval Research (ONR), and San Marcos Middle School (SMMS), IFRR brings physical oceanography and related sciences to students at the San Marcos Middle School in real-time from research vessels at sea using SIO's HiSeasNet satellite communication system. With a generous grant from ONR, students are able to tour the SIO ships and spend a day at sea doing real oceanographic data collection and labs. Through real-time and near-realtime broadcasts and webcasts, students are able to share data with scientists and gain an appreciation for the value of biogeochemical research in the field as it relates to their classroom studies. The primary impact on these students is an appreciation of ocean science as it relates to their lives. Interaction with scientists and researchers as well as crew members gives students insights into not only possible career paths, but the vital importance of cutting edge oceanographic research on our society. With their science teacher on the ship as an education outreach specialist or ashore guiding students in their interactions with selected scientists at sea, students observe shipboard research being carried out live via videoconference, Skype, daily e-mails, interviews, digital whiteboard sessions, and web interaction. Students then research, design, develop, deploy, and field-test their own data-collecting physical oceanography instruments in their classroom. The online interactive curriculum encourages active inquiry with intellectually stimulating problem- solving, enabling students to gain critical insight and skill while investigating some of the most provocative questions of our time, and seeing scientists as role-models. Over the last seven years science test scores with IFRR students have shown significant increases in classes where this curriculum has been implemented as compared to other classes where the traditional curriculum has been used. IFRR has provided students in the San Diego area with a unique opportunity for learning about oceanographic research, which could inspire students to become oceanographers or at least scientifically literate citizens, a benefit for a country that depends increasingly on technically proficient personnel, and a benefit for society at large.

Communicating Ocean Science at the Lower-Division Level

NASA Astrophysics Data System (ADS)

Coopersmith, A.

2011-12-01

Pacific Ocean Literacy for Youth, Publics, Professionals, and Scientists (POLYPPS) is an NSF-funded collaboration between the University of Hawai`i and the Center for Ocean Science Education Excellence (COSEE) - California, which is based at the Lawrence Hall of Science, University of California - Berkeley. One of the objectives of this project is to instutionalize ocean science communications courses at colleges and universities in Hawai`i. Although the focus of most of these communications courses has been on training graduate students and scientists, lower-division students interested in the ocean sciences are finding this background helpful. At the University of Hawai`i Maui College there are several marine science courses and certificate programs that require students to interact with the public through internships, research assistantships, and course-related service-learning projects. Oceanography 270, Communicating Ocean Science, is now offered to meet the needs of these students who engage with the public in informal educational settings. Other students who enroll in this course have a general interest in the marine environment and are considering careers in K-12 formal education. This course gives this group of students an opportunity to explore formal education by assisting classroom teachers and preparing and presenting problem-based, hands-on, inquiry activities. Employers at marine-related businesses and in the tourist industry have welcomed this course with a focus on communication skills and indicate that they prefer to hire local people with strong backgrounds in marine and natural sciences. A basic premise of POLYPPS is that science education must draw not only from the latest advances in science and technology but also from the cultural contexts in which the learners are embedded and that this will achieve increased understanding and stewardship of ocean environments. Students in Oceanography 270 integrate traditional Hawaiian knowledge into their activities and presentations with the advice of local practitioners who share their experiences for incorporating both Hawaiian ways of learning and environmental practices.

Facilitating the Transition of Nurse Clinician to Nurse Scientist: Significance of Entry PhD Courses.

PubMed

Armstrong, Deborah K; McCurry, Mary; Dluhy, Nancy M

Transitioning into the role of nurse scientist requires the acquisition of new knowledge but also involves the development of new scholarly skills and the appropriation of the unique values and goals of the new role. Students engaged in doctor of philosophy education in all practice disciplines are confronted with a necessary shift in perspective and identity from that of the practice expert to the research scientist and experience a tension referred to as the research-practice dualism. The purpose of this article is to examine the ramifications of this identity shift in nursing doctor of philosophy education and to detail one program's strategy to address the inherent tension. This transition into the role of nurse scientist includes learning to value scholarly literature, expanding one's philosophical and disciplinary vocabulary, cultivating disciplinary inquisitiveness, learning scholarly communication and dissemination skills, and developing new collegial relationships. It is essential that this process of transitioning from clinician to scholar be purposively supported from the outset of the program. Faculty must critically examine current educational strategies and design new approaches to more effectively integrate the practice and science worlds, thereby enhancing program completion and graduating nurse scientists who are equipped to contribute to the knowledge of the discipline. Copyright © 2016 Elsevier Inc. All rights reserved.

Community Coordinated Modeling Center: A Powerful Resource in Space Science and Space Weather Education

NASA Astrophysics Data System (ADS)

Chulaki, A.; Kuznetsova, M. M.; Rastaetter, L.; MacNeice, P. J.; Shim, J. S.; Pulkkinen, A. A.; Taktakishvili, A.; Mays, M. L.; Mendoza, A. M. M.; Zheng, Y.; Mullinix, R.; Collado-Vega, Y. M.; Maddox, M. M.; Pembroke, A. D.; Wiegand, C.

2015-12-01

Community Coordinated Modeling Center (CCMC) is a NASA affiliated interagency partnership with the primary goal of aiding the transition of modern space science models into space weather forecasting while supporting space science research. Additionally, over the past ten years it has established itself as a global space science education resource supporting undergraduate and graduate education and research, and spreading space weather awareness worldwide. A unique combination of assets, capabilities and close ties to the scientific and educational communities enable this small group to serve as a hub for raising generations of young space scientists and engineers. CCMC resources are publicly available online, providing unprecedented global access to the largest collection of modern space science models (developed by the international research community). CCMC has revolutionized the way simulations are utilized in classrooms settings, student projects, and scientific labs and serves hundreds of educators, students and researchers every year. Another major CCMC asset is an expert space weather prototyping team primarily serving NASA's interplanetary space weather needs. Capitalizing on its unrivaled capabilities and experiences, the team provides in-depth space weather training to students and professionals worldwide, and offers an amazing opportunity for undergraduates to engage in real-time space weather monitoring, analysis, forecasting and research. In-house development of state-of-the-art space weather tools and applications provides exciting opportunities to students majoring in computer science and computer engineering fields to intern with the software engineers at the CCMC while also learning about the space weather from the NASA scientists.

How Do School Peers Influence Student Educational Outcomes? Theory and Evidence from Economics and Other Social Sciences

ERIC Educational Resources Information Center

Harris, Douglas N.

2010-01-01

Background: Interest among social scientists in peer influences has grown with recent resegregation of the nation's schools and court decisions that limit the ability of school districts to consider race in school assignment decisions. If having more advantaged peers is beneficial, then these trends may reduce educational equity. Previous studies…

Mindfulness Practices for Accounting and Business Education: A New Perspective

ERIC Educational Resources Information Center

Borker, David R.

2013-01-01

For more than a decade, researchers in accounting and business education have focused on the concept of mindfulness as a source of ideas that contribute to transforming the classroom experience and the quality of student learning. This research is founded on the work of social scientists studying the general application of mindfulness to teaching…

Field-Based Professional Development of Teachers Engaged in Distance Education: Experiences from the Arctic

ERIC Educational Resources Information Center

Veletsianos, George; Doering, Aaron; Henrickson, Jeni

2012-01-01

We examine the experiences of five teachers who traveled with a team of educators, scientists, and explorers on circumpolar Arctic expeditions to deliver adventure learning (AL) programs to K-12 students at a distance. Results highlight the personal and professional impacts this opportunity had on teachers, including their empowering, fulfilling,…

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,…

Enhancing Science Education Instruction: A Mixed-Methods Study on University and Middle School Collaborations

ERIC Educational Resources Information Center

Owen-Stone, Deborah S.

2012-01-01

The purpose of this concurrent mixed methods study was to examine the collaborative relationship between scientists and science teachers and to incorporate and advocate scientific literacy based on past and current educational theories such as inquiry based teaching. The scope of this study included archived student standardized test scores,…

The Present and Future of MFT Doctoral Education in Research-Focused Universities

ERIC Educational Resources Information Center

Sprenkle, Douglas H.

2010-01-01

Doctoral education is greatly impacted by context, and the large majority of marital and family therapy (MFT) doctoral programs are PhD programs in research-focused universities. I believe their primary mission is to equip students to become scientist-practitioners and do original research that will advance the science of the discipline, whereas…

NASA's Initiative to Develop Education through Astronomy (IDEA)

NASA Astrophysics Data System (ADS)

Bennett, Jeffrey O.; Morrow, Cherilynn A.

1994-04-01

We describe a progressive program in science education called the Initiative to Develop Education through Astronomy (IDEA). IDEA represents a commitrnent by the Astrophysics Division of NASA Headquarters to pre-collegiate and public learning. The program enlists the full participation of research astronomers in taking advantage of the natural appeal of astronomy and the unique features of space astrophysics missions to generate valuable learning experiences and scientifically accurate and educationally effective products for students, teachers and citizens. One of the premier projects is called Flight Opportunities for Science Teacher EnRichment (FOSTER) — a program to fly teachers aboard the Kuiper Airborne Observatory during actual research missions. IDEA is managed by a visiting scientist with extensive educational background (each of the authors have served in this role), and the program is unique within NASA science divisions for having a full time scientist devoted to education. IDEA recognizes that the rapidly shifting social and political landscape has caused a fundamental change in how science is expected to contribute to society. It is in the enlightened self-interest of all research scientists to respond to the challenge of connecting forefront research to basic educational needs. IDEA is exploring the avenues needed to facilitate these connections, including supplementing research grants for educational purposes.

NASA's initiative to develop education through astronomy (IDEA)

NASA Technical Reports Server (NTRS)

Bennett, Jeffrey O.; Morrow, Cherilynn A.

1994-01-01

We describe a progressive program in science education called the Initiative to Develop Education through Astronomy (IDEA). IDEA represents a commitment by the Astrophysics Division of NASA Headquarters to pre-collegiate and public learning. The program enlists the full participation of research astronomers in taking advantage of the natural appeal of astronomy and the unique features of space astrophysics missions to generate valuable learning experiences and scientifically accurate and educationally effective products for students, teachers and citizens. One of the premier projects is called Flight Opportunities for Science Teacher EnRichment (FOSTER) - a program to fly teachers aboard the Kuiper Airborne Observatory during actual research missions. IDEA is managed by a visiting scientist with extensive educational background (each of the authors have served in this role), and the program is unique within NASA science divisions for having a full time scientist devoted to education. IDEA recognizes that the rapidly shifting social and political landscape has caused a fundamental change in how science is expected to contribute to society. It is in the enlightened self-interest of all research scientists to respond to the challenge of connecting forefront research to basic educational needs. IDEA is exploring the avenues needed to facilitate these connections, including supplementing research grants for educational purposes.

Recent Science Education Initiatives at the Princeton Plasma Physics Laboratory

NASA Astrophysics Data System (ADS)

Zwicker, Andrew; Dominguez, Arturo; Gershman, Sophia; Guilbert, Nick; Merali, Aliya; Ortiz, Deedee

2013-10-01

An integrated approach to program development and implementation has significantly enhanced a variety of Science Education initiatives for students and teachers. This approach involves combining the efforts of PPPL scientists, educators, research and education fellows, and collaborating non-profit organizations to provide meaningful educational experiences for students and teachers. Our undergraduate internship program continues to have outstanding success, with 72% of our participants going to graduate school and 45% concentrating in plasma physics. New partnerships have allowed us to increase the number of underrepresented students participating in mentored research opportunities. The number of participants in our Young Women's Conference increases significantly each year. Our Plasma Camp workshop, now in its 15th year, recruits outstanding teachers from around the country to create new plasma-centered curricula. Student research in the Science Education Laboratory concentrates on the development of a high-fidelity plasma speaker, a particle dropper for a dusty plasma experiment, microplasmas along liquid surfaces for a variety of applications, an Internet-controlled DC glow discharge source for students, and a Planeterrella for demonstrating the aurora and other space weather phenomenon for the general public.

Student Journalists in the Field: Bridging the Gap Between Science and Communication

NASA Astrophysics Data System (ADS)

Glotch, T. D.; Jones, A. P.; Bleacher, L.; Selvin, B.; Firstman, R.

2015-12-01

The Remote, In Situ, and Synchrotron Studies for Science and Exploration (RIS4E) team is one of nine nodes of NASA's Solar System Exploration Research Virtual Institute. A core goal of the RIS4E Education and Communication (E&C) plan is to increase the accessibility of science to the general public, both by teaching scientists how to communicate their work to the public and by training the next generation of science journalists. During the Spring 2015 semester, eight Stony Brook University journalism students, ranging from Sophomores through M.A. students, participated in a new Science Journalism course in the School of Journalism. During the semester, the students learned about the science being conducted by the RIS4E team, took field trips to labs, interviewed scientists and graduate students, and produced print and video pieces about the science and the scientists. As a capstone project, five of the students, along with a professor and TA, were embedded with the RIS4E field geology team during their 2015 field season at the 1974 Kilauea lava flow on the Big Island of Hawaii. During their time in Hawaii, the journalism students had complete access to the field team, both during work and after-work hours. For each of the students, it was their first exposure to the practice of science, made possible through the experience of watching scientists formulate and test hypotheses in real time. They posted daily blog updates about the work being done by the field team and acquired dozens of hours of video footage to be produced into longer pieces. This presentation will describe the unique Stony Brook Science Journalism course and the experiences of the students both in the classroom and in the field. We will highlight both the successes and the lessons learned, for both the students and the scientists involved, and discuss our plans to conduct a second class in 2017, when the students will accompany the RIS4E field team to the Potrillo Volcanic Field in New Mexico.

Marine Technology for Teachers and Students: A Multi-modal Approach to Integrate Technology and Ocean Sciences Instruction

NASA Astrophysics Data System (ADS)

Gingras, A.; Knowlton, C. W.; Scowcroft, G. A.; Babb, I.; Coleman, D.; Morin, H.

2016-02-01

The Marine Technology for Teachers and Students (MaTTS) Project implements a year-long continuum of activities beginning with educators reading and reporting on peer-reviewed publications, followed by face-to-face, hands-on weekend workshops and virtual professional development activities. Teams of teacher and student leaders then participate in an intensive, residential Summer Institute (SI) that emphasizes hands-on building of marine related technologies and exposure to career pathways through direct interactions with ocean scientists and engineers. During the school year, teachers integrate ocean science technology and data into their classrooms and participate, along with colleagues and students from their schools, in science cafes and webinars. Student leaders transfer knowledge gained by engaging their district's middle school students in ocean science activities and technologies by serving as hosts for live broadcasts that connect classrooms with ocean scientists and engineers though the Inner Space Center, a national ocean science telecommunications hub. Communication technologies bridge formal and informal learning environments, allowing MaTTS participants to interact with their fellow cohort members, scientists, and engineers both during and outside of school. Evaluation results indicate that for teachers both the weekend workshops and SI were most effective in preparing them to integrate ocean science and technology in STEM curricula and increase their ocean science content knowledge and leadership characteristics. For students the SI and the middle school interactions supported gains in knowledge, awareness, leadership skills and interest in ocean sciences and technologies, and related STEM careers. In particular, the connections made by working directly with scientists have positively impacted both student and teacher leaders. This presentation will provide an overview of the MaTTS model and early evaluation results.

Improvement in Student Science Proficiency Through InSciEd Out

PubMed Central

Sonju, James D.; Leicester, Jean E.; Hoody, Maggie; LaBounty, Thomas J.; Frimannsdottir, Katrin R.; Ekker, Stephen C.

2012-01-01

Abstract Integrated Science Education Outreach (InSciEd Out) is a collaboration formed between Mayo Clinic, Winona State University, and Rochester Public Schools (MN) with the shared vision of achieving excellence in science education. InSciEd Out employs an equitable partnership model between scientists, teachers, education researchers, and the community. Teams of teachers from all disciplines within a single school experience cutting-edge science using the zebrafish model system, as well as current pedagogical methods, during a summer internship at the Mayo Clinic. Within the internship, the teachers produce new curriculum that directly addresses opportunities for science education improvement at their own school. Zebrafish are introduced within the new curriculum to support a living model of the practice of science. Following partnership with the InSciEd Out program and 2 years of implementation in the classroom, teacher-interns from a K–8 public school reported access to local scientific technology and expertise they had not previously recognized. Teachers also reported improved integration of other disciplines into the scientific curriculum and a flow of concepts vertically from K through 8. Students more than doubled selection of an Honors science track in high school to nearly 90%. 98% of students who took the Minnesota Comprehensive Assessments in their 5th and 8th grade year (a span that includes 2 years of InSciEd Out) showed medium or high growth in science proficiency. These metrics indicate that cooperation between educators and scientists can result in positive change in student science proficiency and demonstrate that a higher expectation in science education can be achieved in US public schools. PMID:23244687

Leveraging, Synergies and Cloning: Thoughts on How Scientists can Multiply their Impact on Education and Public Outreach

NASA Astrophysics Data System (ADS)

Chambers, L. H.

2011-12-01

An individual scientist might look at the huge numbers of students and the public who constitute a potential audience for education and public outreach (EPO) and conclude that he/she has no hope to make a difference. This talk will share some strategies that have the potential to multiply a scientist's for maximum effect, and some evidence that indeed one person CAN make a difference. The first strategy is to leverage: that is, find a person or group who already has an ongoing EPO activity that relates to your subject area, and use it as a way to get your information out to an existing, interested audience. This benefits you because you don't have to begin from scratch to build an audience for your information, and it benefits them because they get great new content to keep their audience interested. The second strategy is to synergize: that is, cooperate or coordinate with an existing EPO group, or with colleagues with similar interests. Use your expertise to develop new resources that fit into an existing program. Cooperate with an existing EPO group so they can help you navigate details like review processes, aligning your resource to education standards, and helping tailor your information to the needs of the education audience. The third strategy is to use technology to approximate cloning: that is, to propagate yourself and your information via multiple channels. However, this strategy should not be used until after you have tested and honed your information through a number of in-person interactions with the audience(s) you seek to reach, and have developed some communications skills that help you connect with students and teachers. One lesson that you may learn from such interactions is that scientists aren't like other people. We have a distinct vocabulary, culture, and habits of mind that distinguish us from others. This is a key strength for science, but sometimes a barrier for EPO. By personal contact with non-scientists, we can learn again how to communicate outside of science. There is one major difference between the communication scientists normally do, at conferences such as AGU, and that which they do for EPO: novelty vs. repetition. While scientists seek to present the latest discovery to each other, 4th graders need to learn basically the same thing every year. Thus, the information you share with students does not need to be totally cutting edge; it should ideally draw connections between the fundamentals they are learning and exciting areas of recent scientific inquiry. Once you have figured out a message and style that works with live audiences, it is time to explore how emerging technologies can multiply your impact beyond that achieved by individual in-person interactions. Technology is advancing rapidly, and new and better options are continually becoming available: webinars, video, QR codes, the list goes on! Again, collaboration and cooperation are key strategies here: join forces with technical experts, EPO groups who use these new tools, and other interested individuals with key knowledge. The bottom line of scientists doing EPO: It's worth it! Studies show that a very small fraction of people in the US actually know a scientist. It is important for scientists to get out there and demonstrate that, in fact, scientists are real people!

Lunar and Planetary Science XXXV: Engaging K-12 Educators, Students, and the General Public in Space Science Exploration

NASA Technical Reports Server (NTRS)

2004-01-01

The session "Engaging K-12 Educators, Students, and the General Public in Space Science Exploration" included the following reports:Training Informal Educators Provides Leverage for Space Science Education and Public Outreach; Teacher Leaders in Research Based Science Education: K-12 Teacher Retention, Renewal, and Involvement in Professional Science; Telling the Tale of Two Deserts: Teacher Training and Utilization of a New Standards-based, Bilingual E/PO Product; Lindstrom M. M. Tobola K. W. Stocco K. Henry M. Allen J. S. McReynolds J. Porter T. T. Veile J. Space Rocks Tell Their Secrets: Space Science Applications of Physics and Chemistry for High School and College Classes -- Update; Utilizing Mars Data in Education: Delivering Standards-based Content by Exposing Educators and Students to Authentic Scientific Opportunities and Curriculum; K. E. Little Elementary School and the Young Astronaut Robotics Program; Integrated Solar System Exploration Education and Public Outreach: Theme, Products and Activities; and Online Access to the NEAR Image Collection: A Resource for Educators and Scientists.

Helping Scientists Become Effective Partners in Education and Outreach

NASA Astrophysics Data System (ADS)

Laursen, Sandra L.; Smith, Lesley K.

2009-01-01

How does a scientist find herself standing before a group of lively third-graders? She may be personally motivated-seeking to improve public understanding of scientific issues and the nature of science, or to see her own children receive a good science education-or perhaps she simply enjoys this kind of work [Andrews et al., 2005; Kim and Fortner, 2008]. In addition to internal motivating factors, federal funding agencies have begun to encourage scientists to participate in education and outreach (E/O) related to their research, through NASA program requirements for such activities (see ``Implementing the Office of Space Science Education/Public Outreach Strategy,'' at http://spacescience.nasa.gov/admin/pubs/edu/imp_plan.htm) and the U.S. National Science Foundation's increased emphasis on ``broader impacts'' in merit review of research proposals (see http://www.nsf.gov/pubs/2003/nsf032/bicexamples.pdf). Universities, laboratories, and large collaboratives have responded by developing E/O programs that include interaction between students, teachers, and the public in schools; after-school and summer programs; and work through science centers, planetaria, aquaria, and museums.

The Role of Student-Advisor Interactions in Apprenticing Undergraduate Researchers into a Scientific Community of Practice

NASA Astrophysics Data System (ADS)

Thiry, Heather; Laursen, Sandra L.

2011-12-01

Among science educators, current interest in undergraduate research (UR) is influenced both by the traditional role of the research apprenticeship in scientists' preparation and by concerns about replacing the current scientific workforce. Recent research has begun to demonstrate the range of personal, professional, and intellectual benefits for STEM students from participating in UR, yet the processes by which student-advisor interactions contribute to these benefits are little understood. We employ situated learning theory (Lave and Wenger, Situated learning: legitimate peripheral participation, Cambridge University Press, Cambridge in 1991) to examine the role of student-advisor interactions in apprenticing undergraduate researchers, particularly in terms of acculturating students to the norms, values, and professional practice of science. This qualitative study examines interviews with a diverse sample of 73 undergraduate research students from two research-extensive institutions. From these interviews, we articulate a continuum of practices that research mentors employed in three domains to support undergraduate scientists-in-training: professional socialization, intellectual support, and personal/emotional support. The needs of novice students differed from those of experienced students in each of these areas. Novice students needed clear expectations, guidelines, and orientation to their specific research project, while experienced students needed broader socialization in adopting the traits, habits, and temperament of scientific researchers. Underrepresented minority students, and to a lesser extent, women, gained confidence from their interactions with their research mentors and broadened their future career and educational possibilities. Undergraduate research at research-extensive universities exemplifies a cycle of scientific learning and practice where undergraduate researchers are mentored by graduate students and postdoctoral researchers, who are themselves apprentices to faculty members. As such, research mentors of undergraduate students should be aware of the dual scientific and educational aspects of their advising role and its significance in shaping students' identities and career trajectories.

KSC-2011-3368

NASA Image and Video Library

2011-05-06

Cape Canaveral, Fla. -- Rachael Power, education specialist sets up a display for fourth- through 12-grade students and their teachers from across the nation during closing events at the NASA Explorer Schools Symposium in Florida. During the NES gathering, students presented their investigation project to their peers, scientists, engineers and education specialists. About 60 fourth- through 12-grade students nationwide are at the center May 4-7 participating in tours of processing and launch facilities and the U.S. Astronaut Hall of Fame, as well as several educational activities and a career panel question-and-answer session. About 30 teachers will receive professional development opportunities during the symposium. The participants were competitively selected after they completed an original investigation focused on existing NASA missions or research interests. Photo Credit: NASA/Kim Shiflett

KSC-2011-3373

NASA Image and Video Library

2011-05-06

Cape Canaveral, Fla. -- Priscilla Moore, NASA Education Programs Specialist, speaks to students from across the nation gathered for the closing events of the NASA Explorer Schools (NES) symposium. During the NES gathering, students presented their investigation project to their peers, scientists, engineers and education specialists. About 60 fourth- through 12-grade students nationwide are at the center May 4-7 participating in tours of processing and launch facilities and the U.S. Astronaut Hall of Fame, as well as several educational activities and a career panel question-and-answer session. About 30 teachers will receive professional development opportunities during the symposium. The participants were competitively selected after they completed an original investigation focused on existing NASA missions or research interests. Photo Credit: NASA/Kim Shiflett

Tracing Fifth-Grade Students' Epistemologies in Modeling through Their Participation in a Model-Based Curriculum Unit

ERIC Educational Resources Information Center

Baek, Hamin

2013-01-01

In the past decade, there has been a growing interest in scientific practices as a reform focus in K-12 science education of the United States. In this context, scientific practices refer to practices that have family resemblance to scientists' professional practices and simultaneously are pedagogically accessible and useful to students. In…

VICE PRESIDENT PENCE VIEWS SOLAR ECLIPSE WITH STUDENTS AT U.S. NAVAL OBSERVATORY

NASA Image and Video Library

2017-08-21

On Monday, Aug. 21, Vice President Mike Pence welcomed students from a Washington area school to the U.S. Naval Observatory, to view the 2017 solar eclipse and learn about heliophysics – the study of our sun. The event was also attended by former NASA astronaut Pam Melroy, NASA scientist Brad Bailey, and education specialist Evelina Felicite-Maurice.

Independent Synthesis Projects in the Organic Chemistry Teaching Laboratories: Bridging the Gap between Student and Researcher

ERIC Educational Resources Information Center

Keller, Valerie A.; Kendall, Beatrice Lin

2017-01-01

Science educators strive to teach students how to be well-rounded scientists with the ability to problem solve, anticipate errors, and adapt to unexpected roadblocks. Traditional organic chemistry experiments seldom teach these skills, no matter how novel or contemporary the subject material. This paper reports on the success of a quarter-long…

The GEP: Crowd-Sourcing Big Data Analysis with Undergraduates.

PubMed

Elgin, Sarah C R; Hauser, Charles; Holzen, Teresa M; Jones, Christopher; Kleinschmit, Adam; Leatherman, Judith

2017-02-01

The era of 'big data' is also the era of abundant data, creating new opportunities for student-scientist research partnerships. By coordinating undergraduate efforts, the Genomics Education Partnership produces high-quality annotated data sets and analyses that could not be generated otherwise, leading to scientific publications while providing many students with research experience. Copyright © 2016 Elsevier Ltd. All rights reserved.

Outreach and Engagement Education for Graduate Students in Natural Resources: Developing a Course to Enrich a Graduate Outreach Requirement

ERIC Educational Resources Information Center

Latimore, Jo A.; Dreelin, Erin A.; Burroughs, Jordan Pusateri

2014-01-01

Scientists need to engage stakeholders in natural resource management; however, few graduate programs prepare students to conduct outreach and engagement. Given this need, the authors' goals were to (1) create a one-credit course that introduced outreach and engagement practices and participatory approaches, (2) improve the quality of graduate…

Careers "From" but Not "In" Science: Why Are Aspirations to Be a Scientist Challenging for Minority Ethnic Students?

ERIC Educational Resources Information Center

Wong, Billy

2015-01-01

The importance of science to the economy and for the progression of society is widely acknowledged. Yet, there are concerns that minority ethnic students in the UK are underrepresented, and even excluded, from post-compulsory science education and careers "in" science. Drawing on an exploratory study of 46 semi-structured interviews with…

How Do Science, Technology, Engineering, and Mathematics Minority Faculty Members Describe Their Experiences of Graduate Student and Faculty Socialization?

ERIC Educational Resources Information Center

Johnson, Ayana M.

2012-01-01

To remain globally competitive in science, technology, engineering, and mathematics (STEM), we must increase our number of underrepresented minority scientists (URMs) as our country's population becomes more diverse. For URMs to move up the educational and professional ranks, they need to be properly socialized as graduate students and…

Journal of Undergraduate Research, Volume VIII, 2008

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

Stiner, K. S.; Graham, S.; Khan, M.

Th e Journal of Undergraduate Research (JUR) provides undergraduate interns the opportunity to publish their scientific innovation and to share their passion for education and research with fellow students and scientists. Fields in which these students worked include: Biology; Chemistry; Computer Science; Engineering; Environmental Science; General Sciences; Materials Sciences; Medical and Health Sciences; Nuclear Sciences; Physics; Science Policy; and Waste Management.

Partial Support of MAST Academy Outreach Program

DTIC Science & Technology

1993-05-25

of studies and level of expertise required for a career in marine science . Lastly, by providing this educational stimulus to students from ethnic...Marine and Atmospheric Science (RSMAS) and from staff scientists at the Atlantic Oceanographic and Meteorological Laboratories of the National...enabled high school students the opportunity to work in a marine science research environment and to more accurately appraise career opportunities in

Picturing Science: The Who, What, and Where of Images in Children's Award-Winning Science Trade Books

ERIC Educational Resources Information Center

Neutze, Donna Lee

2008-01-01

Educators, students, and parents are among those who have stereotypical preconceived ideas about science and scientists. The study reports on a content analysis of graphic images in 303 of the "Outstanding Science Trade Books for Students K-12" from the years 1973 through 2005. Using quantitative and qualitative content analysis, all of the images…

Technology Needs for Teachers Web Development and Curriculum Adaptations

NASA Technical Reports Server (NTRS)

Carroll, Christy J.

1999-01-01

Computer-based mathematics and science curricula focusing on NASA inventions and technologies will enhance current teacher knowledge and skills. Materials and interactive software developed by educators will allow students to integrate their various courses, to work cooperatively, and to collaborate with both NASA scientists and students at other locations by using computer networks, email and the World Wide Web.

Women in a Man's World: The Female Engineers

ERIC Educational Resources Information Center

Durchholz, Pat

1977-01-01

Comparisons and contrasts between female engineers, male engineers, and female scientists are made utilizing freshmen engineering and science students at the University of Cincinnati. Data including attitudes, career influences, parents' educational level, and career advantage ranking are included. (SL)

Graduate Biomedical Science Education Needs a New Philosophy.

PubMed

Bosch, Gundula; Casadevall, Arturo

2017-12-19

There is a growing realization that graduate education in the biomedical sciences is successful at teaching students how to conduct research but falls short in preparing them for a diverse job market, communicating with the public, and remaining versatile scientists throughout their careers. Major problems with graduate level education today include overspecialization in a narrow area of science without a proper grounding in essential critical thinking skills. Shortcomings in education may also contribute to some of the problems of the biomedical sciences, such as poor reproducibility, shoddy literature, and the rise in retracted publications. The challenge is to modify graduate programs such that they continue to generate individuals capable of conducting deep research while at the same time producing more broadly trained scientists without lengthening the time to a degree. Here we describe our first experiences at Johns Hopkins and propose a manifesto for reforming graduate science education. Copyright © 2017 Bosch and Casadevall.

Career Guidance and Counseling in Educating Female Scientists Of a Developing Nation

NASA Astrophysics Data System (ADS)

Olorode, D. O.; Olorode, G. T.

2009-05-01

The study area is Nigeria as a developing nation. A nation that must be developed must devote a high percentage of her resources to support the education of her women. To educate a woman is to educate a nation. This paper seeks to understand the problems of women scientists from the high school level. Three high schools were chosen, two of them are females only while one is a mixed school. Observations reveal that the problems encountered in Nigeria, by females in science education has a lot of link with lack of Career Guidance Counselors at the high school level. Where they have, female students are not advised properly in the sciences, hence majority of the girls end up with the arts and humanities. It is concluded therefore that every high school in a developing nation must have Departments of Guidance and Counseling for Science and Arts Faculties.

Graduate Biomedical Science Education Needs a New Philosophy

PubMed Central

Bosch, Gundula

2017-01-01

ABSTRACT There is a growing realization that graduate education in the biomedical sciences is successful at teaching students how to conduct research but falls short in preparing them for a diverse job market, communicating with the public, and remaining versatile scientists throughout their careers. Major problems with graduate level education today include overspecialization in a narrow area of science without a proper grounding in essential critical thinking skills. Shortcomings in education may also contribute to some of the problems of the biomedical sciences, such as poor reproducibility, shoddy literature, and the rise in retracted publications. The challenge is to modify graduate programs such that they continue to generate individuals capable of conducting deep research while at the same time producing more broadly trained scientists without lengthening the time to a degree. Here we describe our first experiences at Johns Hopkins and propose a manifesto for reforming graduate science education. PMID:29259084

Social stratification and science education: A longitudinal analysis, 1981-1986, of minorities' integration into the scientific talent pool

NASA Astrophysics Data System (ADS)

Mulkey, Lynn M.; Ellis, Ronald S.

It is common knowledge that scientists are those persons who have the unique attributes required to perform in the role, but contrary to what is widely believed, scientists might also be those who have had access to resources of which other members of the population have been deprived. This study investigates the effectiveness of interventions designed to mediate the negative influence of ascription (race and ethnicity) on the scientific talent pool (students having interest and ability in science). Minorities refers to participants representing the major ethnic and racial groups in the New York City school system: Blacks and Hispanics. Cross-tabulations showed that urban underachieving public high school students take significantly more mathematics and science classes, more frequently graduate from high school and more often enroll in college as compared with students of the same population, who were not exposed to the program. These findings on the effectiveness of tutoring, career counseling, exposure to industrial and academic research sites and to scientist role models, and after-school and weekend classes in mathematics and science, reinforce the observations of Thomas (1986) of the importance of prerequisites for increasing participation of minorities in the natural and technical sciences and mathematics. They extend knowledge of factors which lessen the effects of ascription on educational attainment, and which promote meritocratic conditions for achieving a scientific occupation.

Enabling Wide-Scale Computer Science Education through Improved Automated Assessment Tools

NASA Astrophysics Data System (ADS)

Boe, Bryce A.

There is a proliferating demand for newly trained computer scientists as the number of computer science related jobs continues to increase. University programs will only be able to train enough new computer scientists to meet this demand when two things happen: when there are more primary and secondary school students interested in computer science, and when university departments have the resources to handle the resulting increase in enrollment. To meet these goals, significant effort is being made to both incorporate computational thinking into existing primary school education, and to support larger university computer science class sizes. We contribute to this effort through the creation and use of improved automated assessment tools. To enable wide-scale computer science education we do two things. First, we create a framework called Hairball to support the static analysis of Scratch programs targeted for fourth, fifth, and sixth grade students. Scratch is a popular building-block language utilized to pique interest in and teach the basics of computer science. We observe that Hairball allows for rapid curriculum alterations and thus contributes to wide-scale deployment of computer science curriculum. Second, we create a real-time feedback and assessment system utilized in university computer science classes to provide better feedback to students while reducing assessment time. Insights from our analysis of student submission data show that modifications to the system configuration support the way students learn and progress through course material, making it possible for instructors to tailor assignments to optimize learning in growing computer science classes.

Cross-Cultural Collaboration in Earth Science Education

NASA Astrophysics Data System (ADS)

Sparrow, E. B.; Stephens, S.; Gordon, L. S.; Kopplin, M. R.

2006-12-01

Alaskan Native elders, other local experts, scientists and educators worked collaboratively in providing professional development science workshops and follow-up support for K-12 teachers. Cognizant of the commonalities between western science and Native knowledge, the Observing Locally Connecting Globally (OLCG) program blended GLOBE Earth science measurements, traditional knowledge and best teaching practices including culturally responsive science curriculum, in engaging teachers and students in climate change research. Native observations and knowledge were used to scaffold some local environmental studies undertaken by Alaskan teachers and their students. OLCG partnered with the Project Jukebox of the University of Alaska Fairbanks Oral History Program to produce digitized interviews of Native experts and a scientist on climate change. Sample interviews for students to use in asking Native experts about their observations and knowledge on environmental changes as well as other educational materials have been posted on the program website http://www.uaf.edu/olcg. Links to the climate change interviews, the Alaska Cultural Standards for Schools, Teachers and Students, and other relevant resource materials have also been included in the website. Results of pre- and post-institute assessment showed an increase in teacher comfort level with teaching science and integrating Native knowledge in the classroom. Teacher journals indicated the program's positive influence on their math and science teaching methods and curriculum. Student attitude and achievement assessments showed a significant increase in post-test (end of school year) scores from pre-test (beginning of the school year) scores. Other lessons learned from this project will also be presented.

Making a Difference: Education at the 10th International Conference on Zebrafish Development and Genetics

PubMed Central

Liang, Jennifer O.; Pickart, Michael A.; Pierret, Chris; Tomasciewicz, Henry G.

2012-01-01

Abstract Scientists, educators, and students met at the 10th International Conference on Zebrafish Development and Genetics during the 2-day Education Workshop, chaired by Dr. Jennifer Liang and supported in part by the Genetics Society of America. The goal of the workshop was to share expertise, to discuss the challenges faced when using zebrafish in the classroom, and to articulate goals for expanding the impact of zebrafish in education. PMID:23244686

An alternative path to improving university Earth science teaching and developing the geoscience workforce: Postdoctoral research faculty involvement in clinical teacher preparation

NASA Astrophysics Data System (ADS)

Zirakparvar, N. A.; Sessa, J.; Ustunisik, G. K.; Nadeau, P. A.; Flores, K. E.; Ebel, D. S.

2013-12-01

It is estimated that by the year 2020 relative to 2009, there will be 28% more Earth Science jobs paying ≥ $75,000/year1 in the U.S.A. These jobs will require advanced degrees, but compared to all arts and science advanced degrees, the number of physical science M.S. and Ph.D. awarded per year decreased from 2.5% in 1980 to 1.5% in 20092. This decline is reflected on a smaller scale and at a younger age: in the New York City school system only 36% of all 8th graders have basic proficiency in science 3. These figures indicate that the lack achievement in science starts at a young age and then extends into higher education. Research has shown that students in grades 7 - 12 4,5 and in university level courses 6 both respond positively to high quality science teaching. However, much attention is focused on improving science teaching in grades 7- 12, whereas at many universities lower level science courses are taught by junior research and contingent faculty who typically lack formal training, and sometimes interest, in effective teaching. The danger here is that students might enter university intending to pursue geoscience degrees, but then encounter ineffective instructors, causing them to lose interest in geoscience and thus pursue other disciplines. The crux of the matter becomes how to improve the quality of university-level geoscience teaching, without losing sight of the major benchmark of success for research faculty - scholarly publications reporting innovative research results. In most cases, it would not be feasible to sidetrack the research goals of early career scientists by placing them into a formal teacher preparation program. But what happens when postdoctoral research scientists take an active role in clinical teacher preparation as part of their research appointments? The American Museum of Natural History's Masters of Arts in Teaching (AMNH-MAT) urban residency pilot program utilizes a unique approach to grade 7 - 12 Earth Science teacher preparation in that postdoctoral research scientists are directly involved in the clinical preparation of the teacher candidates7. In this program, professional educators and senior scientists guide and work closely with the postdoctoral scientists in developing lessons and field experiences for the teacher candidates. This exposes the postdoctoral scientists to pedagogical techniques. Furthermore, postdoctoral scientists make regular visits to partner schools and share their research interests with high school science students8. Regular assessments about the quality of the postdoctoral scientist's teaching, in the form of course evaluations and informal discussions with the teacher candidates and professional educators, further augments the postdoctoral scientists teaching skills. These experiences can ultimately improve university level science teaching, should the postdoctoral scientists find positions within a university setting. Here, five postdoctoral researchers present self-studies of changing instructional practice born of their involvement in clinical teacher preparation in the AMNH-MAT program.

Involving Practicing Scientists in K-12 Science Teacher Professional Development

NASA Astrophysics Data System (ADS)

Bertram, K. B.

2011-12-01

The Science Teacher Education Program (STEP) offered a unique framework for creating professional development courses focused on Arctic research from 2006-2009. Under the STEP framework, science, technology, engineering, and math (STEM) training was delivered by teams of practicing Arctic researchers in partnership with master teachers with 20+ years experience teaching STEM content in K-12 classrooms. Courses based on the framework were offered to educators across Alaska. STEP offered in-person summer-intensive institutes and follow-on audio-conferenced field-test courses during the academic year, supplemented by online scientist mentorship for teachers. During STEP courses, teams of scientists offered in-depth STEM content instruction at the graduate level for teachers of all grade levels. STEP graduate-level training culminated in the translation of information and data learned from Arctic scientists into standard-aligned lessons designed for immediate use in K-12 classrooms. This presentation will focus on research that explored the question: To what degree was scientist involvement beneficial to teacher training and to what degree was STEP scientist involvement beneficial to scientist instructors? Data sources reveal consistently high levels of ongoing (4 year) scientist and teacher participation; high STEM content learning outcomes for teachers; high STEM content learning outcomes for students; high ratings of STEP courses by scientists and teachers; and a discussion of the reasons scientists indicate they benefited from STEP involvement. Analyses of open-ended comments by teachers and scientists support and clarify these findings. A grounded theory approach was used to analyze teacher and scientist qualitative feedback. Comments were coded and patterns analyzed in three databases. The vast majority of teacher open-ended comments indicate that STEP involvement improved K-12 STEM classroom instruction, and the vast majority of scientist open-ended comments focus on the benefits scientists received from networking with K-12 teachers. The classroom lessons resulting from STEP have been so popular among teachers, the Alaska Department of Education and Early Development recently contracted with the PI to create a website that will make the STEP database open to teachers across Alaska. When the Alaska Department of Education and Early Development launched the new website in August 2011, the name of the STEP program was changed to the Alaska K-12 Science Curricular Initiative (AKSCI). The STEP courses serving as the foundation to the new AKSCI site are located under the "History" tab of the new website.

Cultivation of science identity through authentic science in an urban high school classroom

NASA Astrophysics Data System (ADS)

Chapman, Angela; Feldman, Allan

2017-06-01

This study examined how a contextually based authentic science experience affected the science identities of urban high school students who have been marginalized during their K-12 science education. We examined students' perceptions of the intervention as an authentic science experience, how the experience influenced their science identity, as well as their perceptions about who can do science. We found that the students believed the experience to be one of authentic science, that their science identity was positively influenced by participation in the experience, and that they demonstrated a shift in perceptions from stereotypical to more diverse views of scientists. Implications for science education are discussed.

Careers in Government: Bench Scientist to Policy Wonk

NASA Astrophysics Data System (ADS)

Gebbie, Katharine B.

1998-04-01

The U.S. system for graduate education in physics is arguably the most effective system yet devised for advanced training in physics. Focused as it is on original research, it teaches students to identify significant problems, study them in depth, and communicate the results. Because it trains them to be analytical, adaptable, persevering, and pragmatic problem solvers, it prepares them for a wide variety of nontraditional careers. Hence the demand for physicists by Wall Street and management consultant teams. Yet, as stressed in the 1995 report by the Committee on Science, Engineering and Public Policy (COSEPUP)("Reshaping the Graduate Education of Scientists and Engineers," COSEPUP; National Academy of Sciences/National Academy of Engineering/Institute of Medicine. National Academy Press, 1995), what is lacking is exposure to career information and guidance. Many students appear to be unaware of the range and richness of opportunities outside academe. In an effort to fill this gap, illustrative examples of diverse careers and career changes in government will be presented, together with examples of cooperative programs that can enhance the student's appreciation of career possibilities.

Engaging Students Through Classroom Connection Webinars to Improve Their Understanding of the Mars Science Laboratory Mission

NASA Technical Reports Server (NTRS)

Graff, Paige V.; Achilles, Cherie

2013-01-01

Planetary exploration missions to other worlds, like Mars, can generate a lot of excitement and wonder for the public. The Mars Science Laboratory Mission is one of the latest planetary missions that has intrigued the public perhaps more than most. How can scientists and educational specialists capitalize on the allure of this mission and involve students and teachers in a way that not only shares the story of the mission, but actively engages classrooms with scientists and improves their understanding of the science? The Expedition Earth and Beyond (EEAB) Program [1], facilitated by the Astromaterials Research and Exploration Science (ARES) Directorate Education Program at the NASA Johnson Space Center achieves this by facilitating MSL mission focused classroom connection webinars. Five MSL-focused webinars facilitated through EEAB during the 2012 fall semester engaged almost 3000 students and teachers. Involved STEM experts/role models helped translate the science behind the Mars Science Laboratory mission in a comprehensive, exciting, and engaging manner. These virtual events captured participants attention while increasing their science awareness and understanding of the MSL mission.

The trials, tribulations, and triumphs of black faculty in the math and science pipeline: A life history approach

NASA Astrophysics Data System (ADS)

Williams, Lisa D.

2000-12-01

This study explores the career progression and life history of black mathematicians and scientists who teach on university faculties in the United States. It investigates the following questions: Why are there so few black mathematicians and scientists in colleges and universities in the United States? What is the experience of black students who express an interest in science and math? What barriers do black scientists and mathematicians face as they move through school towards their career in higher education? What factors facilitate their success? The current literature shows that there are few women and minorities teaching or working in math and science compared to white men, although reasons for this underrepresentation are still not well understood. I explored this phenomenon by conducting two sets of in-depth interviews with twelve black faculty, six women, six men, from both historically black and predominantly white higher educational institutions in the United States. My interviews were based upon a life history approach that identified the participants' perceptions of the barriers and obstacles, as well as the supports and facilitators encountered in their schooling and career progression. The findings from the study show the importance of a strong family, community, and teacher support for the participants throughout their schooling. Support systems continued to be important in their faculty positions. These support systems include extended family members, teachers, community members, supervisors, and classmates, who serve as role models and mentors. The life study interviews provide striking evidence of the discrimination, isolation, and harassment due to race and gender experienced by black male and female mathematicians and scientists. The racial discrimination and the compounding effect of racism and sexism play out differently for the male and female participants in this study. This study suggests directions for future research on the experiences of young black students who are currently in the math and science educational pipeline. It also offers recommendations for ways in which parents, teachers, administrators, faculty, advisors, and government officials can enhance the educational experiences of black students who express interest and have skills in math and science.

Take One Boat: from offshore science to onshore art

NASA Astrophysics Data System (ADS)

Cotterill, C.

2017-12-01

The International Ocean Discovery Program (IODP) is a collaborative programme that works to explore the oceans and the rocks beneath them. Working from shallow to deep waters, and in ice covered to more tropical areas, scientists work together to sample ocean sediments and rocks, and install subsea observatories, in order to investigate our planets dynamic history. The European Consortium for Ocean Research Drilling (ECORD) are one arm of IODP, and the Education and Outreach Task Force are investigating ways of taking education and outreach further - how can we convey the excitement of this program to others and inspire careers in STEM subjects?Cape Farewell are a think / do tank who gather artists, designers, filmmakers and writers to interact with scientists and find ways to address climate change. From creation of internationally touring artworks to films and novels, Cape Farewell continues to educate engage and inspire. For 3 years the author was involved in Cape Farewell not only as a research scientist, but also as a mentor within the educational programme. Over the course of two expeditions, students were invited to design both a science research project and an accompanying arts project that investigated climate change in this fragile environment, replicating the model used for professional scientists and artists. The long term aim of the project was to support peer to peer learning, with students working as youth ambassadors within their schools and communities. With outputs from this style of engagement now including digital artwork exhibitions, a multi-disciplinary arts school, online resources and the initiation of the youth climate change summit, this talk investigates what lessons can be learnt from this dynamic combination of arts and science, to develop a programme that takes just one boat, and makes a big change in how we communicate science. "The art the students have been producing has been inspired by the science they have learnt, what they experienced during the voyage and their own narratives of being in the Arctic. Unlike school, boundaries between subjects have not been important. Their learning was experiential and in many cases the voyage was a life changing experience" Subathra Subramaniam, Choreographer and science teacher

International Space Station Accomplishments Update: Scientific Discovery, Advancing Future Exploration, and Benefits Brought Home to Earth

NASA Technical Reports Server (NTRS)

Thumm, Tracy; Robinson, Julie A.; Alleyne, Camille; Hasbrook, Pete; Mayo, Susan; Johnson-Green, Perry; Buckley, Nicole; Karabadzhak, George; Kamigaichi, Shigeki; Umemura, Sayaka;

International space station accomplishments update: Scientific discovery, advancing future exploration, and benefits brought home to earth

NASA Astrophysics Data System (ADS)

Thumm, Tracy; Robinson, Julie A.; Alleyne, Camille; Hasbrook, Pete; Mayo, Susan; Buckley, Nicole; Johnson-Green, Perry; Karabadzhak, George; Kamigaichi, Shigeki; Umemura, Sayaka; Sorokin, Igor V.; Zell, Martin; Istasse, Eric; Sabbagh, Jean; Pignataro, Salvatore

2014-10-01

Throughout the history of the International Space Station (ISS), crews on board have conducted a variety of scientific research and educational activities. Well into the second year of full utilization of the ISS laboratory, the trend of scientific accomplishments and educational opportunities continues to grow. More than 1500 investigations have been conducted on the ISS since the first module launched in 1998, with over 700 scientific publications. The ISS provides a unique environment for research, international collaboration and educational activities that benefit humankind. This paper will provide an up to date summary of key investigations, facilities, publications, and benefits from ISS research that have developed over the past year. Discoveries in human physiology and nutrition have enabled astronauts to return from ISS with little bone loss, even as scientists seek to better understand the new puzzle of “ocular syndrome” affecting the vision of up to half of astronauts. The geneLAB campaign will unify life sciences investigations to seek genomic, proteomic and metabolomics of the effect of microgravity on life as a whole. Combustion scientists identified a new “cold flame” phenomenon that has the potential to improve models of efficient combustion back on Earth. A significant number of instruments in Earth remote sensing and astrophysics are providing new access to data or nearing completion for launch, making ISS a significant platform for understanding of the Earth system and the universe. In addition to multidisciplinary research, the ISS partnership conducts a myriad of student led research investigations and educational activities aimed at increasing student interest in science, technology, engineering and mathematics (STEM). Over the past year, the ISS partnership compiled new statistics of the educational impact of the ISS on students around the world. More than 43 million students, from kindergarten to graduate school, with more than 28 million teachers located in 49 countries have participated in some aspect of ISS educational activities. These activities include student-developed investigations, education competitions and classroom versions of ISS investigations, participating in ISS investigator experiments, ISS hardware development, educational demonstrations and cultural activities. Through the many inquiry-based educational activities, students and teachers are encouraged to participate in the ISS program thus motivating the next generation of students to pursue careers in STEM.

Building an early career network through outreach projects: The "mon océan & moi" example

NASA Astrophysics Data System (ADS)

Barbieux, M.; Scheurle, C.; Ardyna, M.; Harmel, T.; Ferraris, M.; Jessin, T.; Lacour, L.; Mayot, N.; Organelli, E.; Pasqueron De Fommervault, O.; Penkerc'h, C.; Poteau, A.; Uitz, J.; Ramondec, S.; Sauzède, R.; Velluci, V.; Claustre, H.

2016-02-01

The ocean plays an important role in the global processes of our planet, from climate change to sea level rise, uptake of carbon dioxide to fisheries stocks. In addition, its scientific importance, extraordinary beauty and public fascination provide perfect ingredients for both education and public outreach. Four years ago, after the launch of the "mon océan & moi" outreach project, an early career network (Ph.D. students and postdocs) has been formed to "promote collaborations/exchanges between the scientific and educational worlds in order to co-elaborate a teaching method for raising the awareness of school children on marine environments". Scientists are pursuing new research yielding improved knowledge and new documentation resources. However, they lack the communication skills to make the subject accessible to the general public. On the other hand, teachers must be informed of recent discoveries and of new resources for educational purposes. To fill this gap, the early career scientists developed, in collaboration with a school authority and an experienced science communicators team, both a trail education program tested directly in middle and high schools and innovative supporting material (i.e., animations, educative video clips and experiments, interactive maps and quizzes). Here we outline a set of guidelines as to how to improve science outreach across a variety of disciplines (e.g., science, technology, engineering) and how this may impact the experience of early career scientists. These tips will be useful for other early career scientists and science outreach projects, large or small, regional, national or international. Such novel outreach initiatives will help educate current and next generations about the importance of ocean environments and the relevance of ocean sciences for the society, and may serve as an example of teamwork for other young scientists.

Promoting seismology education through collaboration between university research scientists and school teachers

NASA Astrophysics Data System (ADS)

Brunt, M. R.; Ellins, K. K.; Boyd, D.; Mote, A. S.; Pulliam, J.; Frohlich, C. A.

2012-12-01

Participation in the NSF-sponsored Texas Earth and Space Science (TXESS) Revolution teacher professional development project paved the way for several teachers to receive educational seismometers and join the IRIS Seismograph in Schools program. This, in turn, has led to secondary school teachers working with university seismologists on research projects. Examples are the NSF-EarthScope SIEDCAR (Seismic Investigation of Edge Driven Convection Associated with the Rio Grande Rift) project; field studies to compile felt-reports for Texas earthquakes, some which may have been induced by human activities; and a seismic study of the Texas Gulf Coast to investigate ocean-continent transition processes along a passive margin. Such collaborations are mutually beneficial in nature. They help scientists to accomplish their research objectives, involve teachers and their students in the authentic, inquiry-based science, promote public awareness of such projects, and open the doors to advancement opportunities for those teachers involved. In some cases, bringing together research scientists and teachers results in collaborations that produce publishable research. In order to effectively integrate seismology research into 7-12 grade education, one of us (Brunt) established the Eagle Pass Junior High Seismology Team in connection with IRIS Seismograph in Schools, station EPTX (AS-1 seismograph), to teach students about earthquakes using authentic real-time data. The concept has sparked interest among other secondary teachers, leading to the creation of two similarly organized seismology teams: WPTX (Boyd, Williams Preparatory School, Dallas) and THTX (Mote, Ann Richards School for Young Women Leaders, Austin). Although the educational seismometers are basic instruments, they are effective educational tools. Seismographs in schools offer students opportunities to learn how earthquakes are recorded and how modern seismometers work, to collect and interpret seismic data, and to experiment with ground shaking. Recognizing this value, researchers in Texas have proposed to create, maintain and promote a Texas Educational Seismic Network (TESN) as a legacy of the NSF-funded EarthScope program. If funding is obtained, 15 educational seismometers will be added to the existing network of 12 to include more university and two-year college (2YC) faculty, and secondary teachers as operators. University operators would partner with and support nearby secondary and 2YC operators.

Bioinformatics core competencies for undergraduate life sciences education.

PubMed

Wilson Sayres, Melissa A; Hauser, Charles; Sierk, Michael; Robic, Srebrenka; Rosenwald, Anne G; Smith, Todd M; Triplett, Eric W; Williams, Jason J; Dinsdale, Elizabeth; Morgan, William R; Burnette, James M; Donovan, Samuel S; Drew, Jennifer C; Elgin, Sarah C R; Fowlks, Edison R; Galindo-Gonzalez, Sebastian; Goodman, Anya L; Grandgenett, Nealy F; Goller, Carlos C; Jungck, John R; Newman, Jeffrey D; Pearson, William; Ryder, Elizabeth F; Tosado-Acevedo, Rafael; Tapprich, William; Tobin, Tammy C; Toro-Martínez, Arlín; Welch, Lonnie R; Wright, Robin; Barone, Lindsay; Ebenbach, David; McWilliams, Mindy; Olney, Kimberly C; Pauley, Mark A

2018-01-01

Although bioinformatics is becoming increasingly central to research in the life sciences, bioinformatics skills and knowledge are not well integrated into undergraduate biology education. This curricular gap prevents biology students from harnessing the full potential of their education, limiting their career opportunities and slowing research innovation. To advance the integration of bioinformatics into life sciences education, a framework of core bioinformatics competencies is needed. To that end, we here report the results of a survey of biology faculty in the United States about teaching bioinformatics to undergraduate life scientists. Responses were received from 1,260 faculty representing institutions in all fifty states with a combined capacity to educate hundreds of thousands of students every year. Results indicate strong, widespread agreement that bioinformatics knowledge and skills are critical for undergraduate life scientists as well as considerable agreement about which skills are necessary. Perceptions of the importance of some skills varied with the respondent's degree of training, time since degree earned, and/or the Carnegie Classification of the respondent's institution. To assess which skills are currently being taught, we analyzed syllabi of courses with bioinformatics content submitted by survey respondents. Finally, we used the survey results, the analysis of the syllabi, and our collective research and teaching expertise to develop a set of bioinformatics core competencies for undergraduate biology students. These core competencies are intended to serve as a guide for institutions as they work to integrate bioinformatics into their life sciences curricula.

Bioinformatics core competencies for undergraduate life sciences education

PubMed Central

Wilson Sayres, Melissa A.; Hauser, Charles; Sierk, Michael; Robic, Srebrenka; Rosenwald, Anne G.; Smith, Todd M.; Triplett, Eric W.; Williams, Jason J.; Dinsdale, Elizabeth; Morgan, William R.; Burnette, James M.; Donovan, Samuel S.; Drew, Jennifer C.; Elgin, Sarah C. R.; Fowlks, Edison R.; Galindo-Gonzalez, Sebastian; Goodman, Anya L.; Grandgenett, Nealy F.; Goller, Carlos C.; Jungck, John R.; Newman, Jeffrey D.; Pearson, William; Ryder, Elizabeth F.; Tosado-Acevedo, Rafael; Tapprich, William; Tobin, Tammy C.; Toro-Martínez, Arlín; Welch, Lonnie R.; Wright, Robin; Ebenbach, David; McWilliams, Mindy; Olney, Kimberly C.

2018-01-01

Although bioinformatics is becoming increasingly central to research in the life sciences, bioinformatics skills and knowledge are not well integrated into undergraduate biology education. This curricular gap prevents biology students from harnessing the full potential of their education, limiting their career opportunities and slowing research innovation. To advance the integration of bioinformatics into life sciences education, a framework of core bioinformatics competencies is needed. To that end, we here report the results of a survey of biology faculty in the United States about teaching bioinformatics to undergraduate life scientists. Responses were received from 1,260 faculty representing institutions in all fifty states with a combined capacity to educate hundreds of thousands of students every year. Results indicate strong, widespread agreement that bioinformatics knowledge and skills are critical for undergraduate life scientists as well as considerable agreement about which skills are necessary. Perceptions of the importance of some skills varied with the respondent’s degree of training, time since degree earned, and/or the Carnegie Classification of the respondent’s institution. To assess which skills are currently being taught, we analyzed syllabi of courses with bioinformatics content submitted by survey respondents. Finally, we used the survey results, the analysis of the syllabi, and our collective research and teaching expertise to develop a set of bioinformatics core competencies for undergraduate biology students. These core competencies are intended to serve as a guide for institutions as they work to integrate bioinformatics into their life sciences curricula. PMID:29870542

Educating the Next Generation of Lunar Scientists

NASA Astrophysics Data System (ADS)

Shaner, A. J.; Shipp, S. S.; Allen, J. S.; Kring, D. A.

2010-12-01

The Center for Lunar Science and Exploration (CLSE), a collaboration between the Lunar and Planetary Institute (LPI) and NASA’s Johnson Space Center (JSC), is one of seven member teams of the NASA Lunar Science Institute (NLSI). In addition to research and exploration activities, the CLSE team is deeply invested in education and outreach. In support of NASA’s and NLSI’s objective to train the next generation of scientists, CLSE’s High School Lunar Research Project is a conduit through which high school students can actively participate in lunar science and learn about pathways into scientific careers. The High School Lunar Research Project engages teams of high school students in authentic lunar research that envelopes them in the process of science and supports the science goals of the CLSE. Most high school students’ lack of scientific research experience leaves them without an understanding of science as a process. Because of this, each team is paired with a lunar scientist mentor responsible for guiding students through the process of conducting a scientific investigation. Before beginning their research, students undertake “Moon 101,” designed to familiarize them with lunar geology and exploration. Students read articles covering various lunar geology topics and analyze images from past and current lunar missions to become familiar with available lunar data sets. At the end of “Moon 101”, students present a characterization of the geology and chronology of features surrounding the Apollo 11 landing site. To begin their research, teams choose a research subject from a pool of topics compiled by the CLSE staff. After choosing a topic, student teams ask their own research questions, within the context of the larger question, and design their own research approach to direct their investigation. At the conclusion of their research, teams present their results and, after receiving feedback, create and present a conference style poster to a panel of lunar scientists. This panel judges the presentations and selects one team to present their research at the annual NLSI Forum. In addition to research, teams interact with lunar scientists during monthly webcasts in which scientists present information on lunar science and careers. Working with school guidance counselors, the CLSE staff assists interested students in making connections with lunar science faculty across the country. Evaluation data from the pilot program revealed that the program influenced some students to consider a career in science or helped to strengthen their current desire to pursue a career in science. The most common feedback from both teachers and mentors was that they would like more direction from CLSE staff. In light of these findings, a few questions arise when looking ahead. How do we meet the needs of our participants without compromising the program’s open inquiry philosophy? Are our expectations simply not clear? How do we keep students excited once the program ends? Is it feasible, as a community, to support them from the moment the program ends until they enter college? Finally, do we have a responsibility as a community to work together to connect students with university faculty?

Helping students make meaning of authentic investigations: findings from a student-teacher-scientist partnership

NASA Astrophysics Data System (ADS)

Peker, Deniz; Dolan, Erin

2012-03-01

As student-teacher-scientist partnerships become more widespread, there is a need for research to understand the roles assumed by scientists and teachers as they interact with students in general and in inquiry learning environments in particular. Although teacher roles during inquiry learning have been studied, there is a paucity of research about the roles that scientists assume in their interactions with students. Socio-cultural perspectives on learning emphasize social interaction as a means for students to make meaning of scientific ideas. Thus, this naturalistic study of classroom discourse aims to explore the ways scientists and teachers help high school students make meaning during authentic inquiry investigations. Conversational analysis is conducted of video recordings of discussions between students and teachers and students and scientists from two instances of a student-teacher-scientist partnership program. A social semiotic analytic framework is used to interpret the actions of scientists and teachers. The results indicate a range of common and distinct roles for scientists and teachers with respect to the conceptual, social, pedagogical, and epistemological aspects of meaning making. While scientists provided conceptual and epistemological support related to their scientific expertise, such as explaining scientific phenomena or aspects of the nature of science, teachers played a critical role in ensuring students' access to this knowledge. The results have implications for managing the division of labor between scientists and teachers in partnership programs.

Helping students make meaning of authentic investigations: findings from a student-teacher-scientist partnership.

PubMed

Peker, Deniz; Dolan, Erin

2012-03-01

As student-teacher-scientist partnerships become more widespread, there is a need for research to understand the roles assumed by scientists and teachers as they interact with students in general and in inquiry learning environments in particular. Although teacher roles during inquiry learning have been studied, there is a paucity of research about the roles that scientists assume in their interactions with students. Socio-cultural perspectives on learning emphasize social interaction as a means for students to make meaning of scientific ideas. Thus, this naturalistic study of classroom discourse aims to explore the ways scientists and teachers help high school students make meaning during authentic inquiry investigations. Conversational analysis is conducted of video recordings of discussions between students and teachers and students and scientists from two instances of a student-teacher-scientist partnership program. A social semiotic analytic framework is used to interpret the actions of scientists and teachers. The results indicate a range of common and distinct roles for scientists and teachers with respect to the conceptual, social, pedagogical, and epistemological aspects of meaning making. While scientists provided conceptual and epistemological support related to their scientific expertise, such as explaining scientific phenomena or aspects of the nature of science, teachers played a critical role in ensuring students' access to this knowledge. The results have implications for managing the division of labor between scientists and teachers in partnership programs.

Russian Higher Educational Institutions' Ability to Compete and the Strict Standards of "Hamburg Scoring"

ERIC Educational Resources Information Center

Plaksii, S.

2009-01-01

Russian universities rank poorly in international comparisons, and recent suggested reforms will not change this situation. There is an urgent need to find ways to improve the quality of Russia's higher education and to make it more appealing to scientists and to international students. In general, in order for the world to begin to appreciate and…

Science Sublime: The Philosophy of the Sublime, Dewey's Aesthetics, and Science Education

ERIC Educational Resources Information Center

Cavanaugh, Shane

2014-01-01

Feelings of awe, wonder, and appreciation have been largely ignored in the working lives of scientists and, in turn, science education has not accurately portrayed science to students. In an effort to bring the affective qualities of science into the classroom, this work draws on the writings of the sublime by Burke, Kant, Emerson, and Wordsworth…

Uncovering Wildlife

ERIC Educational Resources Information Center

Travis, Holly

2016-01-01

Many ground-dwelling amphibians, reptiles, small mammals, insects, and other arthropods seek cover during their resting hours. Their natural hideaways include underground burrows, rotting logs, and leaf litter, which are widely distributed and difficult to discover and observe. To make observation easier, scientists, educators, and students can…

(The Ethics of) Teaching Science and Ethics: A Collaborative Proposal.

PubMed

Kabasenche, William P

2014-12-01

I offer a normative argument for a collaborative approach to teaching ethical issues in the sciences. Teaching science ethics requires expertise in at least two knowledge domains-the relevant science(s) and philosophical ethics. Accomplishing the aims of ethics education, while ensuring that science ethics discussions remain grounded in the best empirical science, can generally best be done through collaboration between a scientist and an ethicist. Ethics as a discipline is in danger of being misrepresented or distorted if presented by someone who lacks appropriate disciplinary training and experience. While there are exceptions, I take philosophy to be the most appropriate disciplinary domain in which to gain training in ethics teaching. Science students, who must be prepared to engage with many science ethics issues, are poorly served if their education includes a misrepresentation of ethics or specific issues. Students are less well prepared to engage specific issues in science ethics if they lack an appreciation of the resources the discipline of ethics provides. My collaborative proposal looks at a variety of ways scientists and ethicists might collaborate in the classroom to foster good science ethics education.

Teacher Workshops in the US: Goals, Best Practices and Impact

NASA Astrophysics Data System (ADS)

Hörst, S. M.

2011-10-01

The goal of the workshop is to educate the teachers on a few focused topics so that they can transfer the knowledge they gain to their students. We will recruit scientists who are attending the meeting to participate in the workshops and will also pair the teachers with scientists in the field who can serve as a resource for the teacher and their class throughout the school year. The scientists can answer questions the teachers may have, be available to do video lectures or interactive question and answer sessions over skype, and work with the teachers to develop hands-on classroom activities. We will partner closely with EPO professionals in NASA's Science Mission Directorate to ensure that best practices for the workshops are employed, including ensuring that the workshop and workshop materials are designed within the framework of the state standards, surveying participating teachers before the workshops about their needs and goals, assessing the participants pre-workshop knowledge, and engaging participants as learners during the workshop [1]. The impact of the workshop will be increased by providing the teachers and students with a scientist who will serve as a long-term resource. We will maintain contact with the teachers after the workshop to ensure that the scientists are still actively engaged in their classroom and to collect feedback. References [1] Shupla C, et al. (2011) Lessons Learned: Best Practices in Educator Workshops. 42nd Lunar and Planetary Science Conference, no. 2828. EPSC Abstracts Vol. 6, EPSC-DPS2011-1775, 2011 EPSC-DPS Joint Meeting 2011 c Author(s) 2011

Engaging Undergraduates in Methods of Communicating Global Climate Change

NASA Astrophysics Data System (ADS)

Hall, C.; Colgan, M. W.; Humphreys, R. R.

2010-12-01

Global Climate Change has become a politically contentious issue in large part because of the failure of scientists to effectively communicate this complex subject to the general public. In a Global Change class, offered within a science department and therefore focused primarily on the underlying science, we have incorporated a citizen science module into the course to raise awareness among future scientists to the importance of communicating information to a broad and diverse audience. The citizen science component of this course focuses on how the predicted climate changes will alter the ecologic and economic landscape of the southeastern region. Helping potential scientists to learn to effectively communicate with the general public is particularly poignant for this predominate southern student body. A Pew Research Center for the People and the Press study found that less than 50% of Southerners surveyed felt that global warming is a very serious problem and over 30% of Southerners did not believe that there was any credible evidence that the Earth is warming. This interdisciplinary and topical nature of the course attracts student from a variety of disciplines, which provides the class with a cross section of students not typically found in most geology classes. This mixture provides a diversity of skills and interest that leads to success of the Citizen Science component. This learning approach was adapted from an education module developed through the Earth System Science Education Alliance and a newly developed component to that program on citizen science. Student teams developed several citizen science-related public service announcements concerning projected global change effects on Charleston and the South Carolina area. The scenario concerned the development of an information campaign for the City of Charleston, culminating with the student presentations on their findings to City officials. Through this real-life process, the students developed new strategies that inform their own means of communicating science, whether to the general public, to peers, or to other scientists. This course with the citizen science component serves as a model for other programs. Incorporating a communication aspect into science courses that revolve around complex but socially important topics, such as global climate change, is necessary in building the confidence in our science students to communicate effectively, imaginatively, and memorably. In addition, the students gain a deeper understanding and appreciation of the necessity to communicate to public audiences and the value of outreach to the community.

Best Practices in NASA's Astrophysics Education and Public Outreach Projects

NASA Astrophysics Data System (ADS)

Hasan, H.; Smith, D.

2015-11-01

NASA's Astrophysics Education and Public Outreach (EPO) program has partnered scientists and educators since its inception almost twenty years ago, leading to authentic STEM experiences and products widely used by the education and outreach community. We present examples of best practices and representative projects. Keys to success include effective use of unique mission science/technology, attention to audience needs, coordination of effort, robust partnerships and publicly accessible repositories of EPO products. Projects are broadly targeted towards audiences in formal education, informal education, and community engagement. All NASA programs are evaluated for quality and impact. New technology is incorporated to engage young students being raised in the digital age. All projects focus on conveying the excitement of scientific discoveries from NASA's Astrophysics missions, advancing scientific literacy, and engaging students in science and technology careers.

Interstellar Molecules in K-12 Education

NASA Astrophysics Data System (ADS)

Kuiper, T. B. H.; Hofstadter, M. D.; Levin, S. M.; MacLaren, D.

2006-12-01

The Lewis Center for Educational Research (LCER) and the Jet Propulsion Laboratory (JPL) collaborate in a K-12 educational project in which students conduct observations for several research programs led by radio astronomers. The Goldstone-Apple Valley Radio Telescope (GAVRT) program provides participating teachers with curriculum elements, based on the students' observing experiences, which support national and state academic standards. The current program is based on 2.2-GHz and 8.4-GHz radiometric observations of variable sources. The research programs monitor Jupiter, Uranus, and a selected set of quasars. The telescope is a decommissioned NASA Deep Space Network antenna at Goldstone, California. In the next three years, a second telescope will be added. This telescope will at least operate at the above frequencies as well as 6 GHz and 12 GHz. Possibly, it will operate in a continuous band from 1.2 GHz to 14 GHz. In either case, the telescope will be able to observe at least the 6.6-GHz and 12.2-GHz methanol maser lines. The success of the GAVRT program depends critically on the participation of scientists committed to the research who have the ability and enthusiasm for interacting with K-12 students, typically through teleconferences. The scientists will initially work with the LCER staff to create curriculum elements around their observing program.

Earth2Class: Bringing the Earth to the Classroom-Innovative Connections between Research Scientists, Teachers, and Students

NASA Astrophysics Data System (ADS)

Passow, M. J.

2017-12-01

"Earth2Class" (E2C) is a unique program offered through the Lamont-Doherty Earth Observatory of Columbia University. It connects research scientists, classroom teachers, middle and high school students, and others in ways that foster broader outreach of cutting-edge discoveries. One key component are Saturday workshops offered during the school year. These provide investigators with a tested format for sharing research methods and results. Teachers and students learn more about "real"science than what is found in textbooks. They discover that Science is exciting, uncertain, and done by people not very different from themselves. Since 1998, we have offered more than 170 workshops, partnering with more than 90 LDEO scientists. E2C teachers establishe links with scientists that have led to participation in research projects, the LDEO Open House, and other programs. Connections developed between high school students and scientists resulted in authentic science research experiences. A second key component of the project is the E2C website, https://earth2class.org/site/. We provide archived versions of monthly workshops. The website hosts a vast array of resources geared to support learning Earth Science and other subjects. Resources created through an NSF grant to explore strategies which enhance Spatial Thinking in the NYS Regents Earth Science curriculum are found at https://earth2class.org/site/?page_id=2957. The site is well-used by K-12 Earth Science educators, averaging nearly 70k hits per month. A third component of the E2C program are week-long summer institutes offering opportunities to enhance content knowledge in weather and climate; minerals, rocks, and resources; and astronomy. These include exploration of strategies to implement NGSS-based approaches within the school curriculum. Participants can visit LDEO lab facilities and interact with scientists to learn about their research. In the past year, we have begun to create a "satellite" E2C program at UFVJM (Universidade Federal dos Vales do Jequinhonha e Mucuri) in Diamantina, Minas Gerais, Brasil. The https://earth2class.org/site/?p=12652 page provides a platform to create similar postings of workshops and educational resources for the Brazilian audience. E2C can serve as a model for similar programs at other institutions.

Integrating Scientists into Teacher Professional Development—Strategies for Success

NASA Astrophysics Data System (ADS)

Lynds, S. E.; Buhr, S. M.; Smith, L. K.

2010-12-01

Professional development workshops for science teachers can be greatly enhanced by scientist participation. Such workshops may promote a collegial community and mutual understanding between researchers and educators. The CIRES (Cooperative Institute for Research in Environmental Sciences) Education and Outreach (EO) group at the University of Colorado, Boulder, has over a decade of experience in successfully developing and hosting such events. Scientist participation in these workshops varies widely—from giving formal presentations to working one-on-one with educators in designing a research project. Researchers from CIRES, NOAA (National Oceanic and Atmospheric Administration), NSIDC (National Snow and Ice Data Center), and other Colorado agencies and institutions have participated in the workshops. In addition, graduate students in scientific research programs at the University of Colorado are frequently involved. Such workshops can be effective broader impacts components of scientific programs. One example of a long-running successful program was the Earthworks project (1998-2007), a one-week workshop for secondary science teachers from around the country. With the help of practicing geoscientists, participants working in teams designed and conducted a field-based interdisciplinary study. Attendees were so enthusiastic that the ongoing Listserv community (including both scientist and educators) is still active and engaged three years after the last workshop. In a more recent example, since 2009 CIRES EO has been hosting an annual week-long summer workshop as the COSEE (Centers for Ocean Science Education Excellence) West—Colorado Collaborative. The COSEE workshops have had a different theme each year. In 2010, the workshop explored the link between Arctic sea ice, the Greenland ice sheet, sea level, and global climate processes. Extensive evaluation efforts have been included in the design of each workshop and the evaluation results are used to improve subsequent workshops. To measure achievement of program goals, feedback surveys, interviews, and workshop observation are employed. Evaluation data have shown consistently throughout the years that both educators and scientists value the time spent with each other at these workshops. Scientists enjoy sharing their topic areas with motivated and energetic educators. Conversely, science teachers appreciate the opportunity to work directly with scientists and to hear about cutting-edge research being done. This paper will review the most successful strategies for including scientists in professional development workshops, from both the teachers’ and the scientists’ perspectives.

'That's What Scientists Have To Do': Preservice Elementary Teachers' Conceptions of the Nature of Science during a Moon Investigation.

ERIC Educational Resources Information Center

Abell, Sandra; Martini, Mariana; George, Melissa

2001-01-01

Describes a science methods course for elementary education majors in which students investigated the phases of the moon. Concludes that students did not make direct connections between their science learning activities and the nature of science. Provides a set of recommendations related to the nature of science and moon study. (Contains 27…

Evaluation of Existing and New Periodic Tables of the Elements for the Chemistry Education of Blind Students

ERIC Educational Resources Information Center

Fantin, Dennis; Sutton, Marc; Daumann, Lena J.; Fischer, Kael F.

2016-01-01

As a symbol of the power and majesty of science, the periodic table has inspired many scientists-to-be to investigate the deep secrets of nature through the study of chemistry. In the spirit of inclusion, blind students too deserve and need to have their curiosity about the inner workings of nature stimulated through greater exposure to this…

The Landsat Image Mosaic of Antarctica (LIMA): A Cutting-Edge Way for Students and Teachers to Learn about Antarctica

ERIC Educational Resources Information Center

Campbell, Brian; Bindschadler, Robert

2009-01-01

By studying Antarctica via satellite and through ground-truthing research, we can learn where the ice is melting and why. The Landsat Image Mosaic of Antarctica (LIMA), a new and cutting-edge way for scientists, researchers, educators, students, and the public to look at Antarctica, supports this research and allows for unprecedented views of our…

Professional Development for Graduate Students through Internships at Federal Labs: an NSF/USGS Collaboration

NASA Astrophysics Data System (ADS)

Snow, E.; Jones, E.; Patino, L. C.; Wasserman, E.; Isern, A. R.; Davies, T.

2016-12-01

In 2013 the White House initiated an effort to coordinate STEM education initiatives across federal agencies. This idea spawned several important collaborations, one of which is a set of National Science Foundation programs designed to place graduate students in federal labs for 2-12 months of their Ph.D. training. The Graduate Research Internship Program (GRIP) and the Graduate Student Preparedness program (GSP) each have the goal of exposing PhD students to the federal work environment while expanding their research tools and mentoring networks. Students apply for supplementary support to their Graduate Research Fellowship (GRIP) or their advisor's NSF award (GSP). These programs are available at several federal agencies; the USGS is one partner. At the U.S. Geological Survey, scientists propose projects, which students can find online by searching USGS GRIP, or students and USGS scientists can work together to develop a research project. At NSF, projects are evaluated on both the scientific merit and the professional development opportunities they afford the student. The career development extends beyond the science (new techniques, data, mentors) into the professional activity of writing the proposal, managing the budget, and working in a new and different environment. The USGS currently has 18 GRIP scholars, including Madeline Foster-Martinez, a UC Berkeley student who spent her summer as a GRIP fellow at the USGS Pacific Coastal and Marine Science Center working with USGS scientist Jessica Lacy. Madeline's Ph.D. work is on salt marshes and she has studied geomorphology, accretion, and gas transport using a variety of research methods. Her GRIP fellowship allowed her to apply new data-gathering tools to the question of sediment delivery to the marsh, and build and test a model for sediment delivery along marsh edges. In addition, she gained professional skills by collaborating with a new team of scientists, running a large-scale field deployment, and experiencing a new work environment. The program is succeeding in mentoring the next generation of geoscientists. At the USGS, we hope that some of these scientists will look for their first full-time job here.

Teaching Small and Thinking Large: Effects of Including Social and Ethical Implications in an Interdisciplinary Nanotechnology Course

PubMed Central

Hoover, Elizabeth; Brown, Phil; Averick, Mara; Kane, Agnes; Hurt, Robert

2013-01-01

One way to ensure that social and ethical implications (SEI) of nanotechnology research are taken into consideration early in research projects is to incorporate ethical concepts into university science education. In this paper, we describe an interdisciplinary nanotechnology university science course and the ways in which the opinions of students regarding the ethical implications of nanotechnology research were influenced by the course. From an SEI perspective, there is value in scientists being aware of the need to make explicit the uncertainties that always exist in scientific and technological research and development. By the end of the class, a majority of the students felt that risks and ethical issues are not well understood by scientists working in nanomaterials, and ethical training was recommended for these scientists. Findings from this study speak to the importance of this type of interdisciplinary class in preparing students for collaborative research and making them aware of issues important to the general public who someday will become consumers of products derived from nanotechnology research. PMID:23585917

Free Workshop for Teachers at the 2013 AGU Fall Meeting

NASA Astrophysics Data System (ADS)

Tamalavage, Anne

2013-10-01

In keeping with its commitment to fostering the next generation of Earth and space scientists, AGU is partnering with the National Earth Science Teachers Association to hold the annual Geophysical Information for Teachers (GIFT) workshop at the 2013 AGU Fall Meeting. GIFT allows K-12 science educators (both classroom and informal) to hear from scientists about their latest Earth and space science research, explore new classroom resources for engaging students, and visit exhibits and technical sessions during the Fall Meeting.