WorldWideScience

Sample records for environmental science education

  1. Activity and Action: Bridging Environmental Sciences and Environmental Education

    Science.gov (United States)

    Tal, Tali; Abramovitch, Anat

    2013-01-01

    The main goal of this study was to examine the Environmental Workshop unit taught to Environmental Sciences majors in the high schools in Israel and learn if, and in what ways, this unit could become a model for environmental education throughout the high school curriculum. We studied the special characteristics of the Environmental Workshop (EW)…

  2. Exploring Mars and Beyond: Science Fiction a Resource for Environmental Education.

    Science.gov (United States)

    Miller, Ryder W.

    The purpose of this article is to show how traditional science fiction, an empowering literature of social criticism, can be used by environmental educators to reach the traditional goals of environmental education. The sub-genres of science fiction are discussed along with ways in which they can be used to reach certain goals of environmental…

  3. Leaving the classroom: a didactic framework for education in environmental sciences

    Science.gov (United States)

    Dopico, Eduardo; Garcia-Vazquez, Eva

    2011-06-01

    In Continuous Education curricula in Spain, the programs on sciences of the environment are aimed toward understandings of sustainability. Teaching practice rarely leaves the classroom for outdoor field studies. At the same time, teaching practice is generally focused on examples of how human activities are harmful for ecosystems. From a pedagogic point of view, it is less effective to teach environmental science with negative examples such as catastrophe, tragedy, and crisis. Rather, teaching environmental sciences and sustainable development might be focused on positive human-environment relationships, which is both important for the further development of students and educators. Within rural settings, there are many such examples of positive relationships that can be emphasized and integrated into the curriculum. In this article, we propose teaching environmental sciences through immersion in rural cultural life. We discuss how fieldwork serves as a learning methodology. When students are engaged through research with traditional cultural practices of environmental management, which is a part of the real and traditional culture of a region, they better understand how positive pedagogy instead of pedagogy structured around how not-to-do examples, can be used to stimulate the interactions between humans and the environment with their students. In this way, cultural goods serve as teaching resources in science and environmental education. What we present is authentic cases where adults involved in a course of Continuous Education explore `environmentally-friendly' practices of traditional agriculture in Asturias (north of Spain), employing methodologies of cultural studies.

  4. A new approach to environmental education: environment-challenge for science, technology and society

    International Nuclear Information System (INIS)

    Popovic, D.

    2002-01-01

    The paper presents a new approach to environmental education within the project Environment: Challenge for Science, Technology and Education, realized on the Alternative Academic Education Network (AAEN) in Belgrade. The project is designed for graduate or advanced undergraduate students of science, medicine, engineering, biotechnology, political and law sciences. It is multidisciplinary and interdisciplinary project aimed to support students interest in different areas of the environmental sciences through strong inter-connection between modern scientific ideas, technological achievements and society. The project contains four basic courses (Living in the Environment; Physical and Chemical Processes in the Environment; Industrial Ecology and Sustainable Development; Environmental Philosophy and Ethics) and a number of elective courses dealing with environmental biology, adaptation processes , global eco politics, environmental ethics, scientific and public policy, environmental consequences of warfare, environmental pollution control, energy management, environmental impact assessment, etc. The standard ex catedra teaching is replaced with active student-teacher communication method enabling students to participate actively in the subject through seminars, workshops, short essays and individual research projects

  5. Science Education for Environmental Awareness: Approaches to Integrating Cognitive and Affective Domains

    Science.gov (United States)

    Littledyke, Michael

    2008-01-01

    Science education has an important part in developing understanding of concepts that underpin environmental issues, leading potentially to pro-environmental behaviour. However, science is commonly perceived negatively, leading to inappropriate and negative models of science that do not connect to people's experiences. The article argues that the…

  6. Learning and teaching for an ecological sense of place: Toward environmental/science education praxis

    Science.gov (United States)

    Hug, J. William

    1998-09-01

    This research presents a teaching model designed to enable learners to construct a highly developed ecological perspective and sense of place. The contextually-based research process draws upon scientific and indigenous knowledge from multiple data sources including: autobiographical experiences, environmental literature, science and environmental education research, historical approaches to environmental education, and phenomenological accounts from research participants. Data were analyzed using the theoretical frameworks of qualitative research, hermeneutic phenomenology, heuristics, and constructivism. The resulting model synthesizes and incorporates key educational philosophies and practices from: nature study, resident outdoor education, organized camping, conservation education, environmental education, earth education, outdoor recreation, sustainability, bio-regionalism, deep ecology, ecological and environmental literacy, science and technology in society, and adventure/challenge/experiential education. The model's four components--environmental knowledge, practicing responsible environmental behaviors, community-focused involvement, and direct experience in outdoor settings--contribute in a synergistic way to the development of ecological perspective and a sense of place. The model was honed through experiential use in an environmental science methods course for elementary and secondary prospective science teachers. The instructor/researcher employed individualized instruction, community-based learning, service learning, and the modeling of reflective teaching principles in pursuit of the model's goals. The resulting pedagogical knowledge extends the model's usefulness to such formal and non-formal educational contexts as: elementary/secondary classrooms, nature centers, museums, youth groups, and community organizations. This research has implications for the fields of education, geography, recreation/leisure studies, science teaching, and environmental

  7. A confluence of traditions: Examining teacher practice in the merging of secondary science and environmental education

    Science.gov (United States)

    Astrid, Steele

    Embedding environmental education within secondary science curriculum presents both philosophical and practical difficulties for teachers. This ethnographic/narrative study, with its methodology grounded in eco-feminism and realism/constructivism, examines the work of six secondary science teachers as they engage in an action research project focused on merging environmental education in their science lessons. Over the course of several months the teachers examine and discuss their views and their professional development related to the project. In the place of definitive conclusions, eight propositions relating the work of secondary science teachers to environmental education, form the basis for a discussion of the implications of the study. The implications are particularly relevant to secondary schools in Ontario, Canada, where the embedding of environmental education in science studies has been mandated.

  8. Educator Preparedness to Teach Environmental Science in Secondary Schools

    Science.gov (United States)

    Guillory, Linus Joseph, Jr.

    2012-01-01

    This study assesses the environmental proficiency of Texas life science educators certified from 2003 to 2011 by analyzing their TExES 138 8-12 exam results in domains V and VI. The sample consisted of all the individuals that took and passed the TExES 138 life science 8-12 exam. During this period, approximately 41% of the individuals who took…

  9. Investigation of Pre-Service Science Teachers' Attitudes towards Sustainable Environmental Education

    Science.gov (United States)

    Keles, Özgül

    2017-01-01

    The purpose of the current study is to investigate pre-service science teachers' sustainable environmental education attitudes and the factors affecting them in terms of some variables (gender and grade level). The study group of the current research is comprised of 154 pre-service teachers attending the Department of Science Education in the…

  10. The Integration of Environmental Education in Science Materials by Using "MOTORIC" Learning Model

    Science.gov (United States)

    Sukarjita, I. Wayan; Ardi, Muhammad; Rachman, Abdul; Supu, Amiruddin; Dirawan, Gufran Darma

    2015-01-01

    The research of the integration of Environmental Education in science subject matter by application of "MOTORIC" Learning models has carried out on Junior High School Kupang Nusa Tenggara Timur Indonesia. "MOTORIC" learning model is an Environmental Education (EE) learning model that collaborate three learning approach i.e.…

  11. Environmental Science for All? Considering Environmental Science for Inclusion in the High School Core Curriculum

    Science.gov (United States)

    Edelson, Daniel C.

    2007-01-01

    With the dramatic growth of environmental science as an elective in high schools over the last decade, educators have the opportunity to realistically consider the possibility of incorporating environmental science into the core high school curriculum. Environmental science has several characteristics that make it a candidate for the core…

  12. Synergetic Use of Crowdsourcing for Environmental Science Research, Applications and Education

    Science.gov (United States)

    Nair, U. S.; Thau, D.

    2015-12-01

    Environmental science research and applications often utilize information that is not readily available or routinely collected by government agencies. Whereas, the quality and quantity of environmental monitoring data is continually improving (e. g., spectral and spatial resolution of satellite imagery) contextual information needed to effectively utilize the data is sparse. Examples of such contextual information include ground truth data for land cover classification, presence/absence of species, prevalence of mosquito breeding sites and characteristics of urban land cover. Often, there are no agencies tasked with routine collection of such contextual information, which could be effectively collected through crowdsourcing. Crowdsourcing of such information, that is useful for environmental science research and applications, also provide opportunities for experiential learning at all levels of education. Appropriately designed crowdsourcing activity can be transform students from passive recipients of information to generators of knowledge. Multiple examples of synergistic use of crowdsourcing, developed by the Public Environmental Education and Research Apps (PEERA) group, at the University of Alabama in Huntsville will be presented. One example is crowdsourcing of land use and land cover (LULC) data using Open Data Kit (ODK) and associated analysis of satellite imagery using Google Earth Engine (GEE). Implementation of this activity as inquiry based learning exercise, for both middle school and for pre-service teachers will be discussed. Another example will detail the synergy between crowdsourcing for biodiversity mapping in southern India and environmental education. Other crowdsourcing activities that offer potential for synergy between research and public education will also be discussed.

  13. Participating in a Citizen Science Monitoring Program: Implications for Environmental Education.

    Directory of Open Access Journals (Sweden)

    Simone Branchini

    Full Text Available Tourism is of growing economical importance to many nations, in particular for developing countries. Although tourism is an important economic vehicle for the host country, its continued growth has led to on-going concerns about its environmental sustainability. Coastal and marine tourism can directly affect the environment through direct and indirect tourist activities. For these reasons tourism sector needs practical actions of sustainability. Several studies have shown how education minimizes the impact on and is proactive for, preserving the natural resources. This paper evaluates the effectiveness of a citizen science program to improve the environmental education of the volunteers, by means of questionnaires provided to participants to a volunteer-based Red Sea coral reef monitoring program (STEproject. Fifteen multiple-choice questions evaluated the level of knowledge on the basic coral reef biology and ecology and the awareness on the impact of human behaviour on the environment. Volunteers filled in questionnaires twice, once at the beginning, before being involved in the project and again at the end of their stay, after several days participation in the program. We found that the participation in STEproject significantly increased both the knowledge of coral reef biology and ecology and the awareness of human behavioural impacts on the environment, but was more effective on the former. We also detected that tourists with a higher education level have a higher initial level of environmental education than less educated people and that the project was more effective on divers than snorkelers. This study has emphasized that citizen science projects have an important and effective educational value and has suggested that tourism and diving stakeholders should increase their commitment and efforts to these programs.

  14. Participating in a Citizen Science Monitoring Program: Implications for Environmental Education

    Science.gov (United States)

    Branchini, Simone; Meschini, Marta; Covi, Claudia; Piccinetti, Corrado; Zaccanti, Francesco; Goffredo, Stefano

    2015-01-01

    Tourism is of growing economical importance to many nations, in particular for developing countries. Although tourism is an important economic vehicle for the host country, its continued growth has led to on-going concerns about its environmental sustainability. Coastal and marine tourism can directly affect the environment through direct and indirect tourist activities. For these reasons tourism sector needs practical actions of sustainability. Several studies have shown how education minimizes the impact on and is proactive for, preserving the natural resources. This paper evaluates the effectiveness of a citizen science program to improve the environmental education of the volunteers, by means of questionnaires provided to participants to a volunteer-based Red Sea coral reef monitoring program (STEproject). Fifteen multiple-choice questions evaluated the level of knowledge on the basic coral reef biology and ecology and the awareness on the impact of human behaviour on the environment. Volunteers filled in questionnaires twice, once at the beginning, before being involved in the project and again at the end of their stay, after several days participation in the program. We found that the participation in STEproject significantly increased both the knowledge of coral reef biology and ecology and the awareness of human behavioural impacts on the environment, but was more effective on the former. We also detected that tourists with a higher education level have a higher initial level of environmental education than less educated people and that the project was more effective on divers than snorkelers. This study has emphasized that citizen science projects have an important and effective educational value and has suggested that tourism and diving stakeholders should increase their commitment and efforts to these programs PMID:26200660

  15. Participating in a Citizen Science Monitoring Program: Implications for Environmental Education.

    Science.gov (United States)

    Branchini, Simone; Meschini, Marta; Covi, Claudia; Piccinetti, Corrado; Zaccanti, Francesco; Goffredo, Stefano

    2015-01-01

    Tourism is of growing economical importance to many nations, in particular for developing countries. Although tourism is an important economic vehicle for the host country, its continued growth has led to on-going concerns about its environmental sustainability. Coastal and marine tourism can directly affect the environment through direct and indirect tourist activities. For these reasons tourism sector needs practical actions of sustainability. Several studies have shown how education minimizes the impact on and is proactive for, preserving the natural resources. This paper evaluates the effectiveness of a citizen science program to improve the environmental education of the volunteers, by means of questionnaires provided to participants to a volunteer-based Red Sea coral reef monitoring program (STEproject). Fifteen multiple-choice questions evaluated the level of knowledge on the basic coral reef biology and ecology and the awareness on the impact of human behaviour on the environment. Volunteers filled in questionnaires twice, once at the beginning, before being involved in the project and again at the end of their stay, after several days participation in the program. We found that the participation in STEproject significantly increased both the knowledge of coral reef biology and ecology and the awareness of human behavioural impacts on the environment, but was more effective on the former. We also detected that tourists with a higher education level have a higher initial level of environmental education than less educated people and that the project was more effective on divers than snorkelers. This study has emphasized that citizen science projects have an important and effective educational value and has suggested that tourism and diving stakeholders should increase their commitment and efforts to these programs.

  16. Depictions of global environmental change in science fiction : an overview of educational applications

    Energy Technology Data Exchange (ETDEWEB)

    Kadonaga, L. [Victoria Univ., BC (Canada). Dept. of Geography

    2000-06-01

    This paper examined how the use of science fiction books and movies can be used as a tool to educate the public. Narratives encourage interest in global environmental changes and can help demystify how science works. Although most science fiction depictions of global environmental change are outdated and oversimplified, the genre can encourage discussion of ecological and social impacts. Writers of science fiction consider both natural systems and human societies, anticipating the work of impacts researchers. It was argued that while both science fiction writers and global change researchers require knowledge and creativity to construct realistic extrapolations, a well-written science fiction book is likely to reach a larger audience. Science fiction books emphasize that climate projections are intended as warnings. If properly handled, they can improve public awareness of issues such as global warming and climatic change. It was suggested that collaboration between researchers and science fiction writers could produce some interesting work. 48 refs.

  17. Science and education across cultures: another look at the Negev Bedouins and their environmental management practices

    Science.gov (United States)

    Saito, Carlos Hiroo

    2014-12-01

    This is a rejoinder to the original article written by Wisam Sedawi, Orit Ben Zvi Assaraf, and Julie Cwikel about waste-related implication on the welfare of children living in the Negev's Bedouin Arab community. More specifically, the authors discuss the role of environmental education in the improvement of participants' life conditions. They do so by analyzing the impact of current precarious waste management practices on children's health and proposing the implementation of a science study unit in school that could assist them in dealing with the problem. My argument here is divided in three parts: first, based on the original article's information, I comment on some important characteristics of those unrecognized settlements and their waste production practices; second, I try to determine what kind of environmental education—if any—is necessary in that context to promote the desired changes put forward by the authors; and third, I adopt a cross-cultural approach to science and environmental literacy as means to provoke readers to consider the scientific value (often neglected) of traditional knowledge in attempting to solve the issues described in the original paper. In addition, both the Tbilisi Intergovernmental Conference on Environmental Education (1977) and the Treaty on Environmental Education for Sustainable Societies and Global Responsibility (1992) are used to support my argument, which also encompasses the concept of empowerment. Ultimately, bridging the Bedouin's traditional knowledge and Western modern science can help to improve science education at the school level in the unrecognized township under study by linking present and past in search of a more sustainable and peaceful future.

  18. Science Education for Environmental Sustainability: A Case Study of the Palouse Watershed

    Science.gov (United States)

    Lyman, Samson E.

    2009-01-01

    This study uses case study and qualitative content analysis methodologies to answer the question: What is the relationship between Washington State's k-12 science education standards and the environmental sustainability needs of the Palouse River Watershed? After defining the Palouse Watershed's attributes, the author presents a land use history…

  19. Expanding the Conversation: Further Explorations into Indigenous Environmental Science Education Theory, Research, and Practice

    Science.gov (United States)

    Lowan, Greg

    2012-01-01

    Indigenous environmental science education is a diverse, dynamic, and rapidly expanding field of research, theory, and practice. This article highlights, challenges, and expands upon key areas of discussion presented by Mack et al. (Cult Stud Sci Educ 7, "2012") as part of the forum on their article "Effective Practices for Creating…

  20. Rethinking Environmental Science Education from Indigenous Knowledge Perspectives: An Experience with a Dene First Nation Community

    Science.gov (United States)

    Datta, Ranjan Kumar

    2018-01-01

    This auto-ethnographic article explores how land-based education might challenge Western environmental science education (ESE) in an Indigenous community. This learning experience was developed from two perspectives: first, land-based educational stories from Dene First Nation community Elders, knowledge holders, teachers, and students; and…

  1. Development environmental attitude of prospective science teachers

    International Nuclear Information System (INIS)

    Iqbal, H.M.

    2000-01-01

    Since the last three decades or so, we have witnessed the growing concern of human beings, all over the world, to adopt measures to conserve and preserve environment of the planet earth, because the same has been threatened by human activity and by way of our unparalleled intervention in the otherwise balanced environment. This awareness and concern has emerged as a need of incorporating environmental Issues into the normal curricula, so that we can educate the young generation to become informed decision-makers of the future. UNESCO and UNEP have advocated (since the last three decades) to teach environmentalised science to students. In Pakistan, there have been attempts to change curricula in accordance with the need of the time. Teachers need new kinds of skills, attitudes and commitment to teach science in an environmentalised fashion. This article discusses the impact of a semester-course on change in environmental attitudes of prospective science-teachers. A pre-test, post-test method was used to ascertain any change in environmental attitude of prospective science-teachers, after studying the environmental education course. It has been shown that there was a change in the environmental attitude of science-teachers as a result of the one-semester course, but the change or the level of attitude was not substantial or satisfactory. There seems to be a need of adopting a comprehensive approach to environmental education, and introducing teaching of environmental concepts at a very early age. (author)

  2. Practical Environmental Education and Local Contribution in the Environmental Science Laboratory Circle in the College of Science and Technology in Nihon University

    Science.gov (United States)

    Taniai, Tetsuyuki; Ito, Ken-Ichi; Sakamaki, Hiroshi

    In this paper, we presented a method and knowledge about a practical and project management education and local contribution obtained through the student activities of “Environmental science laboratory circle in the College of Science and technology in Nihon University” from 1991 to 2001. In this circle, four major projects were acted such as research, protection, clean up and enlightenment projects. Due to some problems from inside or outside of this circle, this circle projects have been stopped. The diffusion and popularization of the internet technology will help to resolve some of these problems.

  3. More than Just Playing Outside: A Self-Study on Finding My Identity as an Environmental Educator in Science Education

    Science.gov (United States)

    Gatzke, Jenna M.; Buck, Gayle A.; Akerson, Valarie L.

    2015-01-01

    The purpose of this study was to investigate the identity conflicts I was experiencing as an environmental educator entering a doctoral program in science education. My inquiry used self-study methodology with a variety of data sources, including sixteen weeks of personal journal entries, audio-recordings of four critical friend meetings, and…

  4. Environmental Science and Engineering Merit Badges: An Exploratory Case Study of a Non-Formal Science Education Program and the U.S. Scientific and Engineering Practices

    Science.gov (United States)

    Vick, Matthew E.; Garvey, Michael P.

    2016-01-01

    The Boy Scouts of America's Environmental Science and Engineering merit badges are two of their over 120 merit badges offered as a part of a non-formal educational program to U.S. boys. The Scientific and Engineering Practices of the U.S. Next Generation Science Standards provide a vision of science education that includes integrating eight…

  5. The Power of One: The Impact of Family and Consumer Sciences Education on Environmental Sustainability

    Science.gov (United States)

    Thompson, Nancy E.

    2010-01-01

    The issues related to environmental sustainability can be overwhelming. It is difficult to imagine that actions of one person could make a difference. This article addresses that perception and illustrates the impact of one person, a family and consumer sciences educator, on the lives of others and on environmental resources. Making a difference…

  6. Prospective Turkish elementary science teachers’ knowledge level about the greenhouse effect and their views on environmental education in university

    OpenAIRE

    Mustafa Kışoğlu; Hasan Gürbüz; Mehmet Erkol; Muhammed Said Akar; Mustafa Akıllı

    2010-01-01

    The fundamental factor of environmental education is teachers who are well-informed about environmental issues. This research aimed to determine prospective Turkish elementary science teachers’ knowledge level about causes, consequences and reducing of the greenhouse effect and to investigate the effect of gender, information source and membership in the environmental foundations on their knowledge. We also aimed to learn their views on environmental education given in universi...

  7. Partnership for Environmental Technology Education

    International Nuclear Information System (INIS)

    Dickinson, Paul R.; Fosse, Richard

    1992-01-01

    The need for broad cooperative effort directed toward the enhancement of science and mathematics education, including environmental science and technology has been recognized as a national priority by government, industry, and the academic community alike. In an effort to address this need, the Partnership for Environmental Technology Education (PETE) has been established in the five western states of Arizona, California, Hawaii, Nevada and Utah. PETE'S overall objectives are to link the technical resources of the DOE, ERA, and NASA Laboratories and private industry with participating community colleges to assist in the development and presentation of curricula for training environmental-Hazardous Materials Technicians and to encourage more transfer students to pursue studies in environmental science at four-year institutions. The program is co-sponsored by DOE and EPA. DoD participation is proposed. PETE is being evaluated by its sponsors as a regional pilot with potential for extension nationally. (author)

  8. Brownfield Action: An education through an environmental science simulation experience for undergraduates

    Science.gov (United States)

    Kelsey, Ryan Daniel

    Brownfield Action is a computer simulation experience used by undergraduates in an Introduction to Environmental Science course for non-science majors at Barnard College. Students play the role of environmental consultants given the semester-long task of investigating a potentially contaminated landsite in a simulated town. The simulation serves as the integration mechanism for the entire course. The project is a collaboration between Professor Bower and the Columbia University Center for New Media Teaching and Learning (CCNMTL). This study chronicles the discovery, design, development, implementation, and evaluation of this project over its four-year history from prototype to full-fledged semester-long integrated lecture and lab experience. The complete project history serves as a model for the development of best practices in contributing to the field of educational technology in higher education through the study of fully designed and implemented projects in real classrooms. Recommendations from the project focus on linking the laboratory and lecture portions of a course, the use of simulations (especially for novice students), instructor adaptation to the use of technology, general educational technology project development, and design research, among others. Findings from the study also emphasize the uniqueness of individual student's growth through the experience, and the depth of understanding that can be gained from embracing the complexity of studying sophisticated learning environments in real classrooms.

  9. Traditional Knowledge Strengthens NOAA's Environmental Education

    Science.gov (United States)

    Stovall, W. K.; McBride, M. A.; Lewinski, S.; Bennett, S.

    2010-12-01

    Environmental education efforts are increasingly recognizing the value of traditional knowledge, or indigenous science, as a basis to teach the importance of stewardship. The National Oceanic and Atmospheric Administration (NOAA) Pacific Services Center incorporates Polynesian indigenous science into formal and informal education components of its environmental literacy program. By presenting indigenous science side by side with NOAA science, it becomes clear that the scientific results are the same, although the methods may differ. The platforms for these tools span a vast spectrum, utilizing media from 3-D visualizations to storytelling and lecture. Navigating the Pacific Islands is a Second Life project in which users navigate a virtual Polynesian voyaging canoe between two islands, one featuring native Hawaiian practices and the other where users learn about NOAA research and ships. In partnership with the University of Hawai‘i Waikiki Aquarium, the Nana I Ke Kai (Look to the Sea) series focuses on connecting culture and science during cross-discipline, publicly held discussions between cultural practitioners and research scientists. The Indigenous Science Video Series is a multi-use, animated collection of short films that showcase the efforts of NOAA fisheries management and ship navigation in combination with the accompanying Polynesian perspectives. Formal education resources and lesson plans for grades 3-5 focusing on marine science have also been developed and incorporate indigenous science practices as examples of conservation success. By merging traditional knowledge and stewardship practices with NOAA science in educational tools and resources, NOAA's Pacific Services Center is helping to build and increase environmental literacy through the development of educational tools and resources that are applicable to place-based understanding and approaches.

  10. Incorporating Hot Topics in Ocean Sciences to Outreach Activities in Marine and Environmental Science Education

    Science.gov (United States)

    Bergondo, D. L.; Mrakovcich, K. L.; Vlietstra, L.; Tebeau, P.; Verlinden, C.; Allen, L. A.; James, R.

    2016-02-01

    The US Coast Guard Academy, an undergraduate military Academy, in New London CT, provides STEM education programs to the local community that engage the public on hot topics in ocean sciences. Outreach efforts include classroom, lab, and field-based activities at the Academy as well as at local schools. In one course, we partner with a STEM high school collecting fish and environmental data on board a research vessel and subsequently students present the results of their project. In another course, cadets develop and present interactive demonstrations of marine science to local school groups. In addition, the Academy develops In another course, cadets develop and present interactive demonstrations of marine science to local school groups. In addition, the Academy develops and/or participates in outreach programs including Science Partnership for Innovation in Learning (SPIL), Women in Science, Physics of the Sea, and the Ocean Exploration Trust Honors Research Program. As part of the programs, instructors and cadets create interactive and collaborative activities that focus on hot topics in ocean sciences such as oil spill clean-up, ocean exploration, tsunamis, marine biodiversity, and conservation of aquatic habitats. Innovative science demonstrations such as real-time interactions with the Exploration Vessel (E/V) Nautilus, rotating tank simulations of ocean circulation, wave tank demonstrations, and determining what materials work best to contain and clean-up oil, are used to enhance ocean literacy. Children's books, posters and videos are some creative ways students summarize their understanding of ocean sciences and marine conservation. Despite time limitations of students and faculty, and challenges associated with securing funding to keep these programs sustainable, the impact of the programs is overwhelmingly positive. We have built stronger relationships with local community, enhanced ocean literacy, facilitated communication and mentorship between young

  11. Towards ecoscience: Environmental and sociocultural perspectives in science. Some insights from Uganda, and implications for higher education

    Science.gov (United States)

    Oluka, Silas Omoding

    This inquiry thus probed into perceptions about science and its applications towards social change and how these are placed in a broader perspective to capture sociocultural and ecological sustainability. Makerere University and an indigenous rural community of Osukuru were used as the setting for the study as they are the acclaimed targets of Ugandan development policies and programs which seek to move the country out of primitivity and backwardness and into a modernized society. A qualitative methodology involving focus group discussions, interviews and a workshop was employed in exploring perceptions, beliefs, assumptions and insights about science and its role in development and environmental conservation, of indigenous perspectives of development, and ecological well-being, and how these are shaped by various worldviews. With little known about how indigenous knowledge and worldviews could work in concert with modern science and technology in the African setting, the study initiated dialogue among scientists government officials, and rural elders towards appropriate harmonization of modern science and technology with local needs and knowledge ways in that promise ecological sustainability and cultural balance. The data indicated that science in Uganda is predominantly regarded as an exploration of natural phenomena and as a body of facts to be memorized or discovered by students within the defined process skills of scientific inquiry, irrespective of context. The nature of the market economy, its application of science and subsequent impacts on society and the environment were not seen as the responsibility of scientists, science research, or discourse. Rather, they were seen as "problems" for the politicians, industrialists and international or corporate organizations. There were no indications of planning, teaching nor research in science and technology education that explored the linkages and issues related to the interactions of economy, society

  12. Activist Environmental Education and Moral Philosophy

    Science.gov (United States)

    Burns, David Patrick; Norris, Stephen P.

    2012-01-01

    In this article the authors respond to a recent special issue of the "Canadian Journal of Science, Mathematics and Technology Education" (Alsop & Bencze, 2010) in which the role of environmental activism in science, mathematics, and technology education (SMTE) was addressed. Although they applaud this Special Issue's invitation to begin a new…

  13. Promoting Science-Policy Education on Global Environmental Issues: The Mercury Game

    Science.gov (United States)

    Selin, N. E.; Stokes, L. C.; Susskind, L. E.

    2011-12-01

    We present initial results from a project focusing on teaching science and engineering students about global environmental policy, funded by a NSF CAREER grant. Despite decades of growing global concern about issues such as ozone depletion, climate change, and toxic chemicals, linking science to policy is a continuing challenge, and few science students receive formal training for effective participation in global negotiations. The focus of the educational activity presented here is the development of a freely-available, interactive teaching tool in the form of a role-play simulation, called "The Mercury Game" (http://mit.edu/mercurygame). The simulation requires players to consider scientific information on an emerging global issue, mercury pollution, and collectively decide whether global policy action is appropriate and what the scope of such action might entail. Playing the game helps participants to explore the consequences of representing scientific uncertainty in various ways in a policy context. The game focuses on the credibility of various sources of technical information, strategies for representing risk and uncertainty, and the balance between scientific and political considerations. It also requires the players to grapple with political considerations, particularly the dynamic between the global "North" (the developed world) and the global "South" (the developing world) at the heart of most political conflicts. Simulation outcomes from running the simulation at two scientific conferences and as part of a graduate-level course on global environmental science and policy will be presented.

  14. Science teacher’s idea about environmental concepts in science learning as the first step of science teacher training

    Science.gov (United States)

    Tapilouw, M. C.; Firman, H.; Redjeki, S.; Chandra, D. T.

    2018-05-01

    To refresh natural environmental concepts in science, science teacher have to attend a teacher training. In teacher training, all participant can have a good sharing and discussion with other science teacher. This study is the first step of science teacher training program held by education foundation in Bandung and attended by 20 science teacher from 18 Junior High School. The major aim of this study is gathering science teacher’s idea of environmental concepts. The core of questions used in this study are basic competencies linked with environmental concepts, environmental concepts that difficult to explain, the action to overcome difficulties and references in teaching environmental concepts. There are four major findings in this study. First finding, most environmental concepts are taught in 7th grade. Second finding, most difficult environmental concepts are found in 7th grade. Third finding, there are five actions to overcome difficulties. Fourth finding, science teacher use at least four references in mastering environmental concepts. After all, teacher training can be a solution to reduce difficulties in teaching environmental concepts.

  15. Environmental consciousness and education relationship: Determination of how environment-based concepts are placed in Turkish science curricula

    Energy Technology Data Exchange (ETDEWEB)

    Oezmen, H. [Karadeniz Technical Univ., Trabzon (Turkey). Dept. of Primary Education; Karamustafaoglu, O. [Amasya Univ. (Turkey). Dept. of Primary Education

    2006-12-15

    generations. During the last decades the trend for environmental protection has expanded in various areas including education. Paraskevopoulos et.al. (1998) state that (a) if people are aware of the need for and the ways of protecting the environment they will act to preserve it, (b) schools should assume responsibility for educating about environmental protection and (c) environmental education can be effective as a part of a school curriculum. Increased concern about the environment has paralleled the development of environmental education in the world. With this regard, both developed and developing countries have taken this reality into consideration in designing curricula for all schools. Some arrangements have also been made in science education curricula in Turkey as a developing country in last decades. Of the various subjects taught in secondary schools, science is often perceived as one that can make a significant contribution to environmental education (Ko and Lee, 2003). Therefore, our primarily aim in this study is to determine how the Turkish science curricula contain environmental concepts after some of the attempts on environmental issues in the world were presented. There have been steady developments of national and international declarations relevant to environmental issues. The first attempt in this regard was the Stockholm Declaration recognized the interdependency between humanity and the environment. The most important results emerged from the declaration were to provide fundamental right to freedom, equality and adequate conditions of life in an environment and to improve the environment for present and future generations (UNESCO, 1972). In addition, this declaration stated the need of environmental education from grade school to adulthood. After this first attempt, a number of similar assemblies were made. In these meetings, some decisions were taken for environmental issues in local and global scale. These meetings are given in Table 1

  16. Human/Nature Discourse in Environmental Science Education Resources

    Science.gov (United States)

    Chambers, Joan M.

    2008-01-01

    It is argued that the view of nature and the relationship between human beings and nature that each of us holds impacts our decisions, actions, and notions of environmental responsibility and consciousness. In this study, I investigate the discursive patterns of selected environmental science classroom resources produced by three disparate…

  17. Choosing and Using Images in Environmental Science Education

    Science.gov (United States)

    Muthersbaugh, Debbie Smick

    2012-01-01

    Although using images for teaching has been a common practice in science classrooms (Gordon & Pea, 1995) understanding the purpose or how to choose images has not typically been intentional. For this dissertation three separate studies relating to choosing and using images are prepared with environmental science in mind. Each of the studies…

  18. Computer science handbook. Vol. 13.3. Environmental computer science. Computer science methods for environmental protection and environmental research

    International Nuclear Information System (INIS)

    Page, B.; Hilty, L.M.

    1994-01-01

    Environmental computer science is a new partial discipline of applied computer science, which makes use of methods and techniques of information processing in environmental protection. Thanks to the inter-disciplinary nature of environmental problems, computer science acts as a mediator between numerous disciplines and institutions in this sector. The handbook reflects the broad spectrum of state-of-the art environmental computer science. The following important subjects are dealt with: Environmental databases and information systems, environmental monitoring, modelling and simulation, visualization of environmental data and knowledge-based systems in the environmental sector. (orig.) [de

  19. Accelerate synthesis in ecology and environmental sciences

    Science.gov (United States)

    Synthesis of diverse knowledge is a central part of all sciences, but especially those such as ecology and environmental sciences which draw information from many disciplines. Research and education in ecology are intrinsically synthetic, and synthesis is increasingly needed to find solutions for en...

  20. 76 FR 77239 - National Institute of Environmental Health Sciences; Notice of Meeting

    Science.gov (United States)

    2011-12-12

    ... Environmental Health Sciences; Notice of Meeting Pursuant to section 10(a) of the Federal Advisory Committee Act.../boards/ibcercc/ . Place: National Institute of Environmental Health Sciences, Building 101, Rodbell... and Education; 93.894, Resources and Manpower Development in the Environmental Health Sciences; 93.113...

  1. Social Cognitive Predictors of Interest in Environmental Science: Recommendations for Environmental Educators

    Science.gov (United States)

    Quimby, Julie L.; Seyala, Nazar D.; Wolfson, Jane L.

    2007-01-01

    The authors examined the influence of social cognitive variables on students' interest in environmental science careers and investigated differences between White and ethnic minority students on several career-related variables. The sample consisted of 161 undergraduate science majors (124 White students, 37 ethnic minority students). Results of…

  2. 76 FR 7881 - Advisory Committee for Environmental Research and Education; Notice of Meeting

    Science.gov (United States)

    2011-02-11

    ... NATIONAL SCIENCE FOUNDATION Advisory Committee for Environmental Research and Education; Notice of... support for environmental research and education. Agenda March 16 Update on recent NSF environmental... Science Foundation announces the following meeting: Name: Advisory Committee for Environmental Research...

  3. 77 FR 6826 - Advisory Committee for Environmental Research and Education; Notice of Meeting

    Science.gov (United States)

    2012-02-09

    ... NATIONAL SCIENCE FOUNDATION Advisory Committee for Environmental Research and Education; Notice of... environmental research and education. Agenda: Wednesday, March 14, 2012 Update on NSF environmental research and... Science Foundation announces the following meeting: Name: Advisory Committee for Environmental Research...

  4. Student Empowerment in an Environmental Science Classroom: Toward a Framework for Social Justice Science Education

    Science.gov (United States)

    Dimick, Alexandra Schindel

    2012-01-01

    Social justice education is undertheorized in science education. Given the wide range of goals and purposes proposed within both social justice education and social justice science education scholarship, these fields require reconciliation. In this paper, I suggest a student empowerment framework for conceptualizing teaching and learning social…

  5. 76 FR 71046 - National Institute of Environmental Health Sciences; Notice of Meeting

    Science.gov (United States)

    2011-11-16

    ... Environmental Health Sciences; Notice of Meeting Pursuant to section 10(a) of the Federal Advisory Committee Act... Environmental Health Sciences, National Institutes of Health, 615 Davis Dr., KEY615/3112, Research Triangle Park... and Education; 93.894, Resources and Manpower Development in the Environmental Health Sciences; 93.113...

  6. 76 FR 13650 - National Institute of Environmental Health Sciences; Notice of Closed Meetings

    Science.gov (United States)

    2011-03-14

    ... Environmental Health Sciences; Notice of Closed Meetings Pursuant to section 10(d) of the Federal Advisory... Training, Nat. Institute of Environmental Health Sciences, P.O. Box 12233, MD EC-30/Room 3171, Research... Environmental Health Sciences Special Emphasis Panel; Review of Educational Grants with an Environmental Health...

  7. Prospective Turkish Elementary Science Teachers' Knowledge Level about the Greenhouse Effect and Their Views on Environmental Education in University

    Science.gov (United States)

    Kisoglu, Mustafa; Gürbüz, Hasan; Erkol, Mehmet; Akar, Muhammed Said; Akilli, Mustafa

    2010-01-01

    The fundamental factor of environmental education is teachers who are well-informed about environmental issues. This research aimed to determine prospective Turkish elementary science teachers' knowledge level about causes, consequences and reducing of the greenhouse effect and to investigate the effect of gender, information source and membership…

  8. The status of environmental education in Illinois public high school science and social studies classrooms

    Science.gov (United States)

    Carter, Jill F.

    Examines relationships among the levels of pre-service and inservice teacher preparation in various topic areas within environmental education (EE) and the levels of implementation of those topic areas in public high school science and social studies classrooms in Illinois. Measures teacher attitudes toward EE. Findings indicate that teachers who had received pre-service/inservice teacher education in EE implemented significantly more EE topics into the curriculum than did teachers who reported receiving no pre-service/inservice teacher education in EE. Findings also indicate that beginning teachers do not implement the EE topics nearly as much as veteran teachers.

  9. Education for Sustainable Development at Notre Dame University--Louaize: Environmental Science Curriculum--A Pre-Phase to the Rucas Project on Education for Sustainable Development

    Science.gov (United States)

    Khalaf-Kairouz, Layla

    2012-01-01

    The Faculty of Natural and Applied Sciences at Notre Dame University--Louaize, conscious to the need of experts in the emerging field of sustainability and to the role that an educational institution plays for the service of the community, introduced into the university curricula a major in environmental science. This paper will present the…

  10. 75 FR 50009 - Advisory Committee for Environmental Research and Education; Notice of Meeting

    Science.gov (United States)

    2010-08-16

    ... NATIONAL SCIENCE FOUNDATION Advisory Committee for Environmental Research and Education; Notice of... support for environmental research and education. Agenda September 8, 2010 Update on recent NSF... Science Foundation announces the following meeting: Name: Advisory Committee for Environmental Research...

  11. Environmental Sciences Division annual progress report for period ending September 30, 1982. Environmental Sciences Division Publication No. 2090

    International Nuclear Information System (INIS)

    1983-04-01

    Separate abstracts were prepared for 12 of the 14 sections of the Environmental Sciences Division annual progress report. The other 2 sections deal with educational activities. The programs discussed deal with advanced fuel energy, toxic substances, environmental impacts of various energy technologies, biomass, low-level radioactive waste management, the global carbon cycle, and aquatic and terrestrial ecology

  12. 76 FR 26311 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2011-05-06

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory.... Institute of Environmental Health Sciences, P.O. Box 12233, MD EC-30/Room 3171, Research Triangle Park, NC... and Education; 93.894, Resources and Manpower Development in the Environmental Health Sciences; 93.113...

  13. Exploring the Effects of Specific, Hands-On Interventions, on Environmental Science Topics in Teacher Education Programs

    Science.gov (United States)

    Bullock, S. M.; Hayhoe, D.

    2012-12-01

    With increased concern over the environment, all Ontario students now study soils, energy conservation, water systems, and climate change & the greenhouse effect in Grades 3, 5, 7, 8 and 10. Unfortunately, many prospective teachers at the elementary and intermediate levels come to teacher education programs with little or no formal science education beyond their own experiences as students in the K-12 system. We devised a series of concept tests (some binary choice, some multiple choice) designed to assess teacher candidates' conceptual understandings of soils, energy, water systems, and climate change and the greenhouse effect - the very content they are expected to teach their future students in the school system. We administered a pre-test to our students at two institutions to establish a baseline of their understanding. Then, we specifically devoted class time to exploring each of these themes in our science curriculum methods courses in order using research-based principles of teaching devoted to promoting conceptual change through the use of hands-on, inquiry approaches in science. After a few months had passed, we again administered the same tests to teacher candidates to measure candidates' conceptual gain. Some teacher candidates also participated in follow-up focus group interviews so that they could have the opportunity to articulate their understandings of concepts in environmental science using their own words. In this poster we will report on data collected for this project over the past two academic years. We have reached two broad conclusions. First, teacher candidates know a considerable amount about the four environmental topics that were selected, despite the fact that most participants in the research did not have post-secondary training in science. For example, participants tended to know that planting different crops on the soil in different years helps to maintain fertile soils and that warmer oceans will cause an increase in the severity of

  14. Prospective Turkish elementary science teachers’ knowledge level about the greenhouse effect and their views on environmental education in university

    Directory of Open Access Journals (Sweden)

    Mustafa KIŞOĞLU

    2010-03-01

    Full Text Available The fundamental factor of environmental education is teachers who are well-informed about environmental issues. This research aimed to determine prospective Turkish elementary science teachers’ knowledge level about causes, consequences and reducing of the greenhouse effect and to investigate the effect of gender, information source and membership in the environmental foundations on their knowledge. We also aimed to learn their views on environmental education given in university. Twenty-six Likert-scale items developed by Cin (2006 were used for data collection. The scale was applied to 215prospective teachers from two universities in eastern Turkey. Results indicated that the majority of prospective teachers had misunderstandings about causes, consequences and reducing of the greenhouse effect. According to the analysis of demographic variables, there were significant differences in participants’ mean scores based on gender and information sources. Additionally, prospective teachers found environmental education inadequate fordifferent reasons.

  15. Prospective Turkish elementary science teachers’ knowledge level about the greenhouse effect and their views on environmental education in university

    Directory of Open Access Journals (Sweden)

    Mustafa Kışoğlu

    2010-03-01

    Full Text Available The fundamental factor of environmental education is teachers who are well-informed about environmental issues. This research aimed to determine prospective Turkish elementary science teachers’ knowledge level about causes, consequences and reducing of the greenhouse effect and to investigate the effect of gender, information source and membership in the environmental foundations on their knowledge. We also aimed to learn their views on environmental education given in university. Twenty-six Likert-scale items developed by Cin (2006 were used for data collection. The scale was applied to 215 prospective teachers from two universities in eastern Turkey. Results indicated that the majority of prospective teachers had misunderstandings about causes, consequences and reducing of the greenhouse effect. According to the analysis of demographic variables, there were significant differences in participants’ mean scores based on gender and information sources. Additionally, prospective teachers found environmental education inadequate for different reasons.

  16. The Effects of Argumentation Implementation on Environmental Education Self Efficacy Beliefs and Perspectives According to Environmental Problems

    Science.gov (United States)

    Fettahlioglu, Pinar

    2018-01-01

    The purpose of this study is to investigate the effect of argumentation implementation applied in the environmental science course on science teacher candidates' environmental education self-efficacy beliefs and perspectives according to environmental problems. In this mixed method research study, convergent parallel design was utilized.…

  17. Interactive Higher Education Instruction to Advance STEM Instruction in the Environmental Sciences - the Brownfield Action Model

    Science.gov (United States)

    Liddicoat, J. C.; Bower, P.

    2015-12-01

    The U.S. Environmental Protection Agency estimates that presently there are over half a million brownfields in the United States, but this number only includes sites for which an Environmental Site Assessment has been conducted. The actual number of brownfields is certainly in the millions and constitutes one of the major environmental issues confronting all communities today. Taught in part or entirely online for more than 15 years in environmental science, engineering, and hydrology courses at over a dozen colleges, universities, and high schools in the United States, Brownfield Action (BA) is an interactive, web-based simulation that combines scientific expertise, constructivist education philosophy, and multimedia to advance the teaching of environmental science (Bower et al., 2011, 2014; Liddicoat and Bower, 2015). In the online simulation and classroom, students form geotechnical consulting companies with a peer chosen at random to solve a problem in environmental forensics. The BA model contains interdisciplinary scientific and social information that are integrated within a digital learning environment that encourages students to construct their knowledge as they learn by doing. As such, the approach improves the depth and coherence of students understanding of the course material. Like real-world environmental consultants and professionals, students are required to develop and apply expertise from a wide range of fields, including environmental science and engineering as well as journalism, medicine, public health, law, civics, economics, and business management. The overall objective is for students to gain an unprecedented appreciation of the complexity, ambiguity, and risk involved in any environmental issue, and to acquire STEM knowledge that can be used constructively when confronted with such an issue.

  18. Advancing Environmental Education and Training for Sustainable Management of Environmental Resources in Palestine

    Science.gov (United States)

    Al-Sa'ed, Rashed; Abu-Madi, Maher; Heun, Jetze

    2009-01-01

    This article describes the various capacity-building activities at the Institute of Environmental and Water Studies of Birzeit University during the past 10 years. It highlights the gained experience in advancing environmental science and engineering education and training programs as components of sustainable water and environmental management…

  19. ESSReS-PEP, an international and interdisciplinary postgraduate education concept on Earth and Environmental Sciences

    Science.gov (United States)

    Grosfeld, Klaus; Lohmann, Gerrit; Ladstätter-Weißenmayer, Annette; Burrows, John

    2013-04-01

    Promoting young researchers is a major priority of the German Helmholtz Association. Since more than five years graduate and postgraduate education in the field of Earth System and Environmental Science has been established in Bremen and Bremerhaven, north-western Germany. Using the network and collaboration of experts and specialists on observational and paleoclimate data as well as on statistical data analysis and climate modelling from two Universities and the Helmholtz research institute on Polar and Marine Research, master and PhD students are trained to understand, decipher and cope with the challenges of recent climate change on an highly interdisciplinary and inter-institutional level. The existing research infrastructure at the Alfred Wegener Institute in Bremerhaven (AWI), University of Bremen, and Jacobs University Bremen offers a unique research environment to study past, present and future changes of the climate system, with special focus on high latitudinal processes. It covers all kind of disciplines, climate science, geosciences and biosciences, and provides a consistent framework for education and qualification of a new generation of expertly trained, internationally competitive master and PhD students. On postgraduate level, the Postgraduate Programme Environmental Physics (PEP) at the University of Bremen (www.pep.uni-bremen.de) educates the participants on the complex relationship between atmosphere, hydrosphere (ocean), cryosphere (ice region) and solid earth (land). Here, the learning of experimental methods in environmental physics at the most advanced level, numerical data analysis using supercomputers, and data interpretation via sophisticated methods prepare students for a scientific career. Within cooperation with the Ocean University of China (OUC) students are participating one year in the PEP programme during their master studies since 2006, to get finally a double degree of both universities. At the Alfred Wegener Institute for Polar

  20. Augmented Citizen Science for Environmental Monitoring and Education

    Science.gov (United States)

    Albers, B.; de Lange, N.; Xu, S.

    2017-09-01

    Environmental monitoring and ecological studies detect and visualize changes of the environment over time. Some agencies are committed to document the development of conservation and status of geotopes and geosites, which is time-consuming and cost-intensive. Citizen science and crowd sourcing are modern approaches to collect data and at the same time to raise user awareness for environmental changes. Citizen scientists can take photographs of point of interests (POI) with smartphones and the PAN App, which is presented in this article. The user is navigated to a specific point and is then guided with an augmented reality approach to take a photo in a specific direction. The collected photographs are processed to time-lapse videos to visualize environmental changes. Users and experts in environmental agencies can use this data for long-term documentation.

  1. Environmental Sciences Division annual progress report for period ending September 30, 1982. Environmental Sciences Division Publication No. 2090. [Lead abstract

    Energy Technology Data Exchange (ETDEWEB)

    1983-04-01

    Separate abstracts were prepared for 12 of the 14 sections of the Environmental Sciences Division annual progress report. The other 2 sections deal with educational activities. The programs discussed deal with advanced fuel energy, toxic substances, environmental impacts of various energy technologies, biomass, low-level radioactive waste management, the global carbon cycle, and aquatic and terrestrial ecology. (KRM)

  2. The Woods Hole Partnership Education Program: Increasing Diversity in the Ocean and Environmental Sciences in One Influential Science Community

    Science.gov (United States)

    Jearld, A.

    2011-12-01

    To increase diversity in one influential science community, a consortium of public and private institutions created the Woods Hole Partnership Education Program, or PEP, in 2008. Participating institutions are the Marine Biological Laboratory, Northeast Fisheries Science Center of NOAA's Fisheries Service, Sea Education Association, U.S. Geological Survey, Woods Hole Oceanographic Institution, the Woods Hole Research Center, and University of Maryland Eastern Shore. Aimed at college juniors and seniors with some course work in marine and/or environmental sciences, PEP is a four-week course and a six-to-eight-week individual research project under the guidance of a research mentor. Forty-six students have participated to date. Investigators from the science institutions serve as course faculty and research mentors. We listened to experts regarding critical mass, mentoring, adequate support, network recruitment, and then built a program based on those features. Three years in we have a program that works and that has its own model for choosing applicants and for matching with mentors. We continue fine-tuning our match process, enhancing mentoring skills, preparing our students for a variety of lab cultures, and setting expectations high while remaining supportive. Our challenges now are to keep at it, using leverage instead of capacity to make a difference. Collaboration, not competition, is key since a rising tide floats all boats.

  3. Bringing the Tools of Big Science to Bear on Local Environmental Challenges

    Science.gov (United States)

    Bronson, Scott; Jones, Keith W.; Brown, Maria

    2013-01-01

    We describe an interactive collaborative environmental education project that makes advanced laboratory facilities at Brookhaven National Laboratory accessible for one-year or multi-year science projects for the high school level. Cyber-enabled Environmental Science (CEES) utilizes web conferencing software to bring multi-disciplinary,…

  4. 1992 Environmental Summer Science Camp Program evaluation. The International Environmental Institute of Westinghouse Hanford Company

    Energy Technology Data Exchange (ETDEWEB)

    1993-07-01

    This report describes the 1992 Westinghouse Hanford Company/US Department of Energy Environmental Summer Science Camp. The objective of the ``camp`` was to motivate sixth and seventh graders to pursue studies in math, science, and the environment. This objective was accomplished through hands-on fun activities while studying the present and future challenges facing our environment. The camp was funded through Technical Task Plan, 424203, from the US Department of Energy-Headquarters, Office of Environmental Restoration and Waste Management, Technology Development,to Westinghouse Hanford Company`s International Environmental Institute, Education and Internship Performance Group.

  5. The 2D Hyperlink/Geocaching hybrid as a New Method for Improving Communication and Educational Delivery in Environmental Science

    Science.gov (United States)

    Graham, J.; Byrne, J. M.

    2009-12-01

    Geocaching is a game of hiding and locating caches (treasures), usually with the aid of a GPS-enabled device, and then posting the locations online for others to discover. Its remarkable success as a cultural phenomenon - transcending the traditional boundaries of age, gender, race and culture, while seamlessly combining the elements of technology, mental challenge, travel, geography, orienteering and entertainment - has been well documented. One would expect, therefore, that something so accessible and so physically, mentally and technologically engaging could also have great potential as an educational tool; specifically for the teaching of environmental science in situ. The attempts to date, however, have been disappointing. It will be the purpose of this poster to demonstrate a new and effective approach to educational environmental science-based geocaching; one which treats discreet elements of the living landscape as caches (rather than obstacles), and which combines several commonly available technologies so as to create a rich, immersive experience for viewers of many ages and backgrounds. Specifically, our poster will demonstrate how traditional geocaching methods can be dramatically improved, for the purposes of education, by combining it with 2D hyperlinking technologies in such a way as to allow the viewer to access a variety of different online and/or offline media elements - documentaries, texts, websites, animations, and images, while immersed in the physical environment to which they relate. It will be shown that this site-specific approach to environmental education has considerable potential for improving the meaningful dialogue between environmental scientists and the general public.

  6. ENVIRONMENTAL PROTECTION AND EDUCATION SYSTEM IN POLAND

    Directory of Open Access Journals (Sweden)

    Małgorzata Falencka-Jabłońska

    2017-10-01

    Full Text Available Pro-environmental education and the effectiveness of its methods are a necessity, decisive for preserving natural resources for successive generations. Educating proper attitudes towards the surrounding nature must be based on sound knowledge gained, supported by observation, experience and experiment. Teaching conducted at all levels environmental science should be based not on boxed knowledge, but on causal thinking skills. Establishing hypotheses and their verification, as well as the variety of methods of understanding the laws of nature, will influence the effective prevention of environmental degradation in the 21st century.

  7. Earth System Science Education Modules

    Science.gov (United States)

    Hall, C.; Kaufman, C.; Humphreys, R. R.; Colgan, M. W.

    2009-12-01

    The College of Charleston is developing several new geoscience-based education modules for integration into the Earth System Science Education Alliance (ESSEA). These three new modules provide opportunities for science and pre-service education students to participate in inquiry-based, data-driven experiences. The three new modules will be discussed in this session. Coastal Crisis is a module that analyzes rapidly changing coastlines and uses technology - remotely sensed data and geographic information systems (GIS) to delineate, understand and monitor changes in coastal environments. The beaches near Charleston, SC are undergoing erosion and therefore are used as examples of rapidly changing coastlines. Students will use real data from NASA, NOAA and other federal agencies in the classroom to study coastal change. Through this case study, learners will acquire remotely sensed images and GIS data sets from online sources, utilize those data sets within Google Earth or other visualization programs, and understand what the data is telling them. Analyzing the data will allow learners to contemplate and make predictions on the impact associated with changing environmental conditions, within the context of a coastal setting. To Drill or Not To Drill is a multidisciplinary problem based module to increase students’ knowledge of problems associated with nonrenewable resource extraction. The controversial topic of drilling in the Arctic National Wildlife Refuge (ANWR) examines whether the economic benefit of the oil extracted from ANWR is worth the social cost of the environmental damage that such extraction may inflict. By attempting to answer this question, learners must balance the interests of preservation with the economic need for oil. The learners are exposed to the difficulties associated with a real world problem that requires trade-off between environmental trust and economic well-being. The Citizen Science module challenges students to translate scientific

  8. 76 FR 47611 - Advisory Committee for Environmental Research And Education; Notice of Meeting

    Science.gov (United States)

    2011-08-05

    ... NATIONAL SCIENCE FOUNDATION Advisory Committee for Environmental Research And Education; Notice of... support for environmental research and education. Agenda September 8, 2011 Update on NSF environmental research and education activities; Update on national and international collaborations; Meeting with the...

  9. 78 FR 9743 - Advisory Committee for Environmental Research and Education; Notice of Meeting

    Science.gov (United States)

    2013-02-11

    ... NATIONAL SCIENCE FOUNDATION Advisory Committee for Environmental Research and Education; Notice of... concerning support for environmental research and education. Agenda March 13, 2013 Update on NSF environmental research and education activities Update on national and international collaborations Update on...

  10. The evolution of Smokey Bear: Environmental education about wildfire for youth

    Science.gov (United States)

    Heidi L. Ballard; Emily Evans; Victoria E. Sturtevant; Pamela. Jakes

    2012-01-01

    Many environmental education programs in the United States educate youth about the prevention of wildfire and its role in ecosystems.We reviewed 50 wildfire education programs for youth (WEY) in the U.S. through an Internet search and interviews with program providers. We investigated whether they reflect current wildfire science, environmental education (EE)...

  11. Web portal on environmental sciences "ATMOS''

    Directory of Open Access Journals (Sweden)

    E. P. Gordov

    2006-01-01

    Full Text Available The developed under INTAS grant web portal ATMOS (http://atmos.iao.ru and http://atmos.scert.ru makes available to the international research community, environmental managers, and the interested public, a bilingual information source for the domain of Atmospheric Physics and Chemistry, and the related application domain of air quality assessment and management. It offers access to integrated thematic information, experimental data, analytical tools and models, case studies, and related information and educational resources compiled, structured, and edited by the partners into a coherent and consistent thematic information resource. While offering the usual components of a thematic site such as link collections, user group registration, discussion forum, news section etc., the site is distinguished by its scientific information services and tools: on-line models and analytical tools, and data collections and case studies together with tutorial material. The portal is organized as a set of interrelated scientific sites, which addressed basic branches of Atmospheric Sciences and Climate Modeling as well as the applied domains of Air Quality Assessment and Management, Modeling, and Environmental Impact Assessment. Each scientific site is open for external access information-computational system realized by means of Internet technologies. The main basic science topics are devoted to Atmospheric Chemistry, Atmospheric Spectroscopy and Radiation, Atmospheric Aerosols, Atmospheric Dynamics and Atmospheric Models, including climate models. The portal ATMOS reflects current tendency of Environmental Sciences transformation into exact (quantitative sciences and is quite effective example of modern Information Technologies and Environmental Sciences integration. It makes the portal both an auxiliary instrument to support interdisciplinary projects of regional environment and extensive educational resource in this important domain.

  12. Education in Environmental Chemistry: Setting the Agenda and Recommending Action. A Workshop Report Summary

    Science.gov (United States)

    Zoller, Uri

    2005-08-01

    Worldwide, the essence of the current reform in science education is a paradigm shift from algorithmic, lower-order cognitive skills (LOCS) teaching to higher-order cognitive skills (HOCS) learning. In the context of education in environmental chemistry (EEC), the ultimate goal is to educate students to be science technology environment society (STES)-literate, capable of evaluative thinking, decision making, problem solving and taking responsible action accordingly. Educators need to translate this goal into effective courses that can be implemented: this includes developing teaching strategies and assessment methodologies that are consonant with the goal of HOCS learning. An international workshop—"Environmental Chemistry Education in Europe: Setting the Agenda"—yielded two main recommendations for those undertaking educational reform in science education, particularly to promote meaningful EEC. The first recommendation concerns integration of environmental sciences into core chemistry courses as well as the development and implementation of HOCS-promoting teaching strategies and assessment methodologies in chemical education. The second emphasizes the development of students' HOCS for transfer, followed by performance assessment of HOCS. This requires changing the way environmental chemistry is typically taught, moving from a narrowly focused approach (applied analytical, ecotoxicological, or environmental engineering chemistry) to an interdisciplinary and multidisciplinary approach.

  13. The Elwha Science Education Project (ESEP): Engaging an Entire Community in Geoscience Education

    Science.gov (United States)

    Young, R. S.; Kinner, F.

    2008-12-01

    Native Americans are poorly represented in all science, technology and engineering fields. This under- representation results from numerous cultural, economic, and historical factors. The Elwha Science Education Project (ESEP), initiated in 2007, strives to construct a culturally-integrated, geoscience education program for Native American young people through engagement of the entire tribal community. The ESEP has developed a unique approach to informal geoscience education, using environmental restoration as a centerpiece. Environmental restoration is an increasingly important goal for tribes. By integrating geoscience activities with community tradition and history, project stakeholders hope to show students the relevance of science to their day-to-day lives. The ESEP's strength lies in its participatory structure and unique network of partners, which include Olympic National Park; the non-profit, educational center Olympic Park Institute (OPI); a geologist providing oversight and technical expertise; and the Lower Elwha Tribe. Lower Elwha tribal elders and educators share in all phases of the project, from planning and implementation to recruitment of students and discipline. The project works collaboratively with tribal scientists and cultural educators, along with science educators to develop curriculum and best practices for this group of students. Use of hands-on, place-based outdoor activities engage students and connect them with the science outside their back doors. Preliminary results from this summer's middle school program indicate that most (75% or more) students were highly engaged approximately 90% of the time during science instruction. Recruitment of students has been particularly successful, due to a high degree of community involvement. Preliminary evaluations of the ESEP's outcomes indicate success in improving the outlook of the tribe's youth towards the geosciences and science, in general. Future evaluation will be likewise participatory

  14. Synthesis for the Interdisciplinary Environmental Sciences: Integrating Systems Approaches and Service Learning

    Science.gov (United States)

    Simon, Gregory L.; Wee, Bryan Shao-Chang; Chin, Anne; Tindle, Amy Depierre; Guth, Dan; Mason, Hillary

    2013-01-01

    As our understanding of complex environmental issues increases, institutions of higher education are evolving to develop new learning models that emphasize synthesis across disciplines, concepts, data, and methodologies. To this end, we argue for the implementation of environmental science education at the intersection of systems theory and…

  15. Globalisation and science education: Rethinking science education reforms

    Science.gov (United States)

    Carter, Lyn

    2005-05-01

    Like Lemke (J Res Sci Teach 38:296-316, 2001), I believe that science education has not looked enough at the impact of the changing theoretical and global landscape by which it is produced and shaped. Lemke makes a sound argument for science education to look beyond its own discourses toward those like cultural studies and politics, and to which I would add globalisation theory and relevant educational studies. Hence, in this study I draw together a range of investigations to argue that globalisation is indeed implicated in the discourses of science education, even if it remains underacknowledged and undertheorized. Establishing this relationship is important because it provides different frames of reference from which to investigate many of science education's current concerns, including those new forces that now have a direct impact on science classrooms. For example, one important question to investigate is the degree to which current science education improvement discourses are the consequences of quality research into science teaching and learning, or represent national and local responses to global economic restructuring and the imperatives of the supranational institutions that are largely beyond the control of science education. Developing globalisation as a theoretical construct to help formulate new questions and methods to examine these questions can provide science education with opportunities to expand the conceptual and analytical frameworks of much of its present and future scholarship.

  16. Identifying barriers to Science, Technology, Society and environment (STSE) educational goals and pedagogy in science education: A case study of UMASS Lowell undergraduate engineering

    Science.gov (United States)

    Phaneuf, Tiffany

    The implementation of sustainable development in higher education is a global trend. Engineers, as gatekeepers of technological innovation, confront increasingly complex world issues ranging from economic and social to political and environmental. Recently, a multitude of government reports have argued that solving such complex problems requires changes in the pedagogy of engineering education, such as that prescribed by the Science, Technology, Society, and education (STS) movement that grew out of the environmental movement in the 70s. In STS students are engaged in the community by understanding that scientific progress is innately a sociopolitical process that involves dimensions of power, wealth and responsibility. United States accreditation criteria now demand "the broad education necessary to understand the impact of engineering solutions in a global, economic, environmental, and societal context" (ABET Engineering Accreditation Commission 2005). With such emphasis on STS education as necessary to address complex world issues, it is vital to assess the barriers in the traditional engineering curriculum that may inhibit the success of such educational reform. This study identifies barriers to STS goals and pedagogy in post secondary science education by using the Francis College of Engineering at UMASS Lowell as a single case study. The study draws on existing literature to develop a theoretical framework for assessing four hypothesized barriers to STS education in undergraduate engineering. Identification of barriers to STS education in engineering generates a critical reflection of post secondary science education and its role in preparing engineers to be active citizens in shaping a rapidly globalizing world. The study offers policy recommendations for enabling post secondary science education to incorporate STS education into its curriculum.

  17. Environmental Science Education at Sinte Gleska University

    Science.gov (United States)

    Burns, D.

    2004-12-01

    At Sinte Gleska University, basically we face two problems 1. The lack of natural resources/environmental education instructors and students. 2. High turnover in the drinking water (and waste water / environmental monitoring) jobs. As soon as people are trained, they typically leave for better paying jobs elsewhere. To overcome these In addition to regular teaching we conduct several workshops year around on environmental issues ranging from tree plantation, preserving water resources, sustainable agriculture and natural therapy (ayurvedic treatment- the Lakota way of treating illness) etc. We offer workshops about the negative impacts brought about by the development and use of hydropower, fossil fuel and nuclear energy (but include topics like reclamation of land after mining). Not only does the harvest and consumption of these energy forms devastate the land and its plants, animals, water and air, but the mental, spiritual, and physical health and culture of Native peoples suffer as well. In contrast, wind power offers an environmentally friendly source of energy that also can provide a source of income to reservations.

  18. 1. National Congress of Environmental Science: Abstracts

    International Nuclear Information System (INIS)

    1995-01-01

    The First National Congress of Environmental Sciences had a plural participation in the environmental thematic. The public universities and the research institutes of the different states of Mexico submitted papers containing proposals of scientific and technological solutions to the problems of management of hazardous wastes: water and land pollution; new methods of evaluation to pollutants of air and water; protection and conservation of relevant species of the ecology; control of genetic alterations; development and conservation of natural resources, and environmental education. Another part of the abstracts is dedicated to the posters session (Author)

  19. Goddard Space Flight Center: 1994 Maryland/GSFC Earth and Environmental Science Teacher Ambassador Program

    Science.gov (United States)

    Latham, James

    1995-01-01

    The Maryland/Goddard Space Flight Center (GSFC) Earth and Environmental Science Teacher Ambassador Program was designed to enhance classroom instruction in the Earth and environmental science programs in the secondary schools of the state of Maryland. In October 1992, more than 100 school system administrators from the 24 local Maryland school systems, the Maryland State Department of Education, and the University of Maryland met with NASA GSFC scientists and education officers to propose a cooperative state-wide secondary school science teaching enhancement initiative.

  20. 77 FR 50532 - Advisory Committee for Environmental Research and Education; Notice of Meeting

    Science.gov (United States)

    2012-08-21

    ... NATIONAL SCIENCE FOUNDATION Advisory Committee for Environmental Research and Education; Notice of... Environmental Research and Education, 9487. Dates: September 12, 2012, 9 a.m.-5 p.m. September 13, 2012, 9 a.m... concerning support for environmental research and education. Agenda September 12, 2012 Update on NSF...

  1. Student desertion study of the program of Natural Sciences and Environmental Education in the period 2011–2015

    Directory of Open Access Journals (Sweden)

    Elvira Patricia Flórez Nisperuza

    2016-12-01

    Full Text Available One of the main problems facing the Colombian Higher Education System concerns high levels of dropout in the undergraduate program, the degree program in Natural Sciences and Environmental Education, Faculty of Education and Human Sciences of the University of Cordoba, Is foreign to this reality. In relation to this problem, the purpose of this research was to characterize and describe the factors that influence the dropout of the program in the period 2011 - 2015. The research was of mixed nature, interviews and surveys were applied to the sample. It is concluded that the factors that influence this phenomenon are the economic factor, lack of vocational guidance, lack of motivation, city change and paternity, to a lesser extent. Finally, this study ends with the proposal of strategies that help to mitigate the problem of desertion, based on the voices of teachers, students, managers and administrators of the program.

  2. Science teaching in science education

    Science.gov (United States)

    Callahan, Brendan E.; Dopico, Eduardo

    2016-06-01

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

  3. 75 FR 9001 - Advisory Committee for Environmental Research and Education; Notice of Meeting

    Science.gov (United States)

    2010-02-26

    ... NATIONAL SCIENCE FOUNDATION Advisory Committee for Environmental Research and Education; Notice of... Research and Education (9487). Dates: March 18, 2010, 8:30 a.m.-5 p.m. March 19, 2010, 8:30 a.m.-1 p.m... support for environmental research and education. Agenda March 18, 2010 Update on recent NSF environmental...

  4. Rural science education as social justice

    Science.gov (United States)

    Eppley, Karen

    2017-03-01

    What part can science education play in the dismantling of obstacles to social justice in rural places? In this Forum contribution, I use "Learning in and about Rural Places: Connections and Tensions Between Students' Everyday Experiences and Environmental Quality Issues in their Community"(Zimmerman and Weible 2016) to explicitly position rural education as a project of social justice that seeks full participatory parity for rural citizens. Fraser's (2009) conceptualization of social justice in rural education requires attention to the just distribution of resources, the recognition of the inherent capacities of rural people, and the right to equal participation in democratic processes that lead to opportunities to make decisions affecting local, regional, and global lives. This Forum piece considers the potential of place-based science education to contribute to this project.

  5. Social Science Collaboration with Environmental Health.

    Science.gov (United States)

    Hoover, Elizabeth; Renauld, Mia; Edelstein, Michael R; Brown, Phil

    2015-11-01

    Social science research has been central in documenting and analyzing community discovery of environmental exposure and consequential processes. Collaboration with environmental health science through team projects has advanced and improved our understanding of environmental health and justice. We sought to identify diverse methods and topics in which social scientists have expanded environmental health understandings at multiple levels, to examine how transdisciplinary environmental health research fosters better science, and to learn how these partnerships have been able to flourish because of the support from National Institute of Environmental Health Sciences (NIEHS). We analyzed various types of social science research to investigate how social science contributes to environmental health. We also examined NIEHS programs that foster social science. In addition, we developed a case study of a community-based participation research project in Akwesasne in order to demonstrate how social science has enhanced environmental health science. Social science has informed environmental health science through ethnographic studies of contaminated communities, analysis of spatial distribution of environmental injustice, psychological experience of contamination, social construction of risk and risk perception, and social impacts of disasters. Social science-environmental health team science has altered the way scientists traditionally explore exposure by pressing for cumulative exposure approaches and providing research data for policy applications. A transdisciplinary approach for environmental health practice has emerged that engages the social sciences to paint a full picture of the consequences of contamination so that policy makers, regulators, public health officials, and other stakeholders can better ameliorate impacts and prevent future exposure. Hoover E, Renauld M, Edelstein MR, Brown P. 2015. Social science collaboration with environmental health. Environ Health

  6. 78 FR 48200 - Advisory Committee for Environmental Research and Education; Notice of Meeting

    Science.gov (United States)

    2013-08-07

    ... NATIONAL SCIENCE FOUNDATION Advisory Committee for Environmental Research and Education; Notice of... Research and Education, 9487. Dates: September 11, 2013, 9:00 a.m.-5:00 p.m., and September 12, 2013, 9:00... research and education. Agenda September 11, 2013 Update on NSF environmental research and education...

  7. Extending the Purposes of Science Education: Addressing Violence within Socio-Economic Disadvantaged Communities

    Science.gov (United States)

    Castano, Carolina

    2012-01-01

    Current discourses about science education show a wide concern towards humanisation and a more socio-cultural perspective of school science. They suggest that science education can serve diverse purposes and be responsive to social and environmental situations we currently face. However, these discourses and social approaches to science education…

  8. Using documentaries for Earth science education

    Science.gov (United States)

    Hooper, Richard; Lilienfeld, Linda; Arrigo, Jennifer

    2011-10-01

    With the success of An Inconvenient Truth, a movie about former U.S. vice president Al Gore's campaign to educate the public on global climate change, long-form documentaries, particularly those concerning environmental issues, are enjoying a renaissance. These films can be a powerful educational tool because they create teachable moments by heightening students' interest in environmental topics. Successful documentaries engage the audience emotionally and tell a compelling story, with heroes and villains. Often films touch on some scientific concepts and may even contain graphics and animations that are useful in explaining processes. However, they generally do not provide a balanced exposition of the science and technical issues that underlie the environmental problems described. Documentaries may advocate a particular policy position.

  9. The development and implementation of a teacher education model in environmental science education for Indian Certificate of Secondary Education (ICSE) schools

    Science.gov (United States)

    Patil, Anuradha

    This research study is concerned with the teaching of Environmental Science in the ninth and tenth grades of ICSE schools in Mumbai, India and the development and implementation of a new teacher education model. The instructional strategies practiced by the teachers were investigated using a questionnaire, semi-structured interview schedule and classroom observation. Based on these data, a new model of teacher education was developed with the help of a small cohort of teachers. The rationale for the model was that it should be a non-prescriptive framework that provided a coherently organized, concise guide for environmental education teachers that incorporated modern perspectives on content knowledge, effective pedagogical practices including constructivist approaches and active learning, and a set of guidelines for effectively integrating pedagogy with science content knowledge. The model was in the form of a two-way matrix, with the columns providing the pedagogy and the rows indicating the content knowledge. The intersections of the columns and rows to form individual cells of the matrix yielded a synthesis of pedagogical content knowledge (PCK). The model was discussed with the participating teachers, who prepared revised lesson plans using the model and delivered the lessons, which were observed by the researcher. On using the model, the teaching became more student-centered, as the teachers strove to include constructive and inquiry-based approaches. The use of technology enhanced the effectiveness of the lessons and teachers evaluated the students on all three domains of learning (i.e., affective, cognitive, and psychomotor). Most teachers agreed that it was possible to use the model to plan their lesson and implement it in the classroom; however, they needed to put in more time and effort to get used to a change in their teaching methodology. There is no doubt that teacher professional development is a long process and change does not occur immediately

  10. The Advanced Technology Environmental Education Center Summer Fellows Institute.

    Science.gov (United States)

    Depken, Diane E.; Zeman, Catherine L.; Lensch, Ellen Kabat; Brown, Edward J.

    2002-01-01

    Describes the background, activities, and outcomes of the Advanced Technology Environmental Education Center (ATEEC) and its Summer Fellows Institutes as a model for disciplinary and cross-disciplinary infusion of environmental science and technology content, curriculum, and methods into the classroom. Presents experiences, themes, and activities…

  11. Environmentalization of the Physical Education Curriculum in Brazilian Universities: Culturally Comparative Lessons from Critical Outdoor Education in Australia

    Science.gov (United States)

    Rodrigues, Cae; Payne, Phillip G.

    2017-01-01

    'Environmentalizing' curriculum in Brazil is a worthy goal of global educational reform for sustainability but is challenging given the limits to rational change thesis already argued in critical social science and post-structural deconstructionism. The federal government mandate to environmentalize undergraduate physical education programs poses…

  12. Environmental Education. Teacher's Handbook, Grade 5.

    Science.gov (United States)

    Nashville - Davidson County Metropolitan Public Schools, TN.

    Prepared for use in the 5th grade, this teacher's handbook consists of 19 science units dealing with environmental education. Topics are ecology, language arts, rocks and fossils, soil, noise pollution, Nashville pioneers and American Indians, conservation, waste and litter, water pollution, compass and mapping, plants and trees, use of the…

  13. The role of entomology in environmental and science education: Comparing outreach methods for their impact on student and teacher content knowledge and motivation

    Science.gov (United States)

    Weeks, Faith J.

    Outreach programming can be an important way for local students and teachers to be exposed to new fields while enhancing classroom learning. University-based outreach programs are offered throughout the country, including most entomology departments as few individuals learn about insects in school and these programs can be excellent sources of entomological education, as well as models to teach environmental and science education. Each department utilizes different instructional delivery methods for teaching about insects, which may impact the way in which students and teachers understand the insect concepts presented. To determine the impact of using entomology to enhance science and environmental education, this study used a series of university-based entomology outreach programs to compare three of the most common delivery methods for their effect on teacher and student content knowledge and motivation, specifically student interest in entomology and teacher self-efficacy. Twenty fifth grade classrooms were assessed over the course of one school year. The results show that teacher knowledge significantly increased when teachers were unfamiliar with the content and when trained by an expert, and teacher self-efficacy did not decrease when asked about teaching with insects. For students, content knowledge increased for each lesson regardless of treatment, suggesting that outreach program providers should focus on working with local schools to integrate their field into the classroom through the delivery methods best suited to the needs of the university, teachers, and students. The lessons also had an impact on student interest in science and environmental education, with an overall finding that student interest increases when using insects in the classroom.

  14. Environmental science: A new opportunity for soil science

    Energy Technology Data Exchange (ETDEWEB)

    Pepper, I.L.

    2000-01-01

    During the golden era of soil science--from the 1950s to the 1980s--the main focus of this discipline was on the role of soil in production agriculture. More recently, renewed interest in the area of environmental science has offered new opportunities to soil scientists. Thus, many soil scientists are now working in areas such as bioremediation, waste recycling, and/or contaminant transport. Environmental science has, therefore, not only changed the traditional research role of soil scientists at land grant institutions but has also influenced student enrollment, the traditional soil science curriculum, and faculty recruitment. These changes require a new breed of soil scientist, one with a background not only in soil science but also in other areas of environmental science as well.

  15. Environmental Sciences Division. Annual progress report for period ending September 30, 1980

    International Nuclear Information System (INIS)

    Auerbach, S.I.; Reichle, D.E.

    1981-03-01

    Research conducted in the Environmental Sciences Division for the Fiscal Year 1980 included studies carried out in the following Division programs and sections: (1) Advanced Fossil Energy Program, (2) Nuclear Program, (3) Environmental Impact Program, (4) Ecosystem Studies Program, (5) Low-Level Waste Research and Development Program, (6) National Low-Level Waste Program, (7) Aquatic Ecology Section, (8) Environmental Resources Section, (9) Earth Sciences Section, and (10) Terrestrial Ecology Section. In addition, Educational Activities and the dedication of the Oak Ridge National Environmental Research Park are reported. Separate abstracts were prepared for the 10 sections of this report

  16. An Ecological System Curriculum: An Integrated MST Approach to Environmental Science Education.

    Science.gov (United States)

    Leonhardt, Nina A.

    This paper describes an inquiry-based, student-centered mathematics, science, and technology curriculum guide. It features activities addressing such environmental science topics as groundwater modeling, water filtration, soil permeability and porosity, water temperature and salinity, and quadrant studies. Activities are organized so that the…

  17. Teaching Professionals Environmental Management: Combining Educational Learning and Practice Learning

    DEFF Research Database (Denmark)

    Jørgensen, Michael Søgaard; Jørgensen, Ulrik

    2003-01-01

    semesters. The target groups are professional environmental managers working in businesses including consultants, governmental institutions and organizations. To get access to the education the students must have a technical/nature science competence at master level or bachelor level combined with relevant...... job experience. Generally the participants have had 5-15 years of practical experience and many have been or are in the position of an internal or external job change towards new tasks that require new knowledge, methodologies or management skills. The education of "Masters of Environmental Management...... they can use in complex situations on the job is not simply a question of combining different university disciplines in the right blend and topping it with some experience. It involves combining science-based knowledge into thematic structures in carefully organized learning processes. The education...

  18. Discourse as mediator in environmental education in a natural science class: a case study

    Directory of Open Access Journals (Sweden)

    Marta Massa

    2004-08-01

    Full Text Available Discourse is an educational practice through which students and teachers are related by a sequence of meanings that are expressed, interchanged, negociated and constructed in the dynamic of a class. In this article, we analize the discursive practices and the arguments that are stated during a Science class when the teacher and her students discuss about the concepts “drinkable water – pollute water” when they are dealing with Environmental Education contents. A qualitative research within the perspective of a case study, centred on discourse analysis, was performed. We examine the content, the resources and the structural features that are used by the teacher and the students in order to construct the arguments and to establish the ideas. Two different templates were detected: the teacher’s, is based on perceptions and operative concepts, while the student’s one is organized in order to seek a microscopic explanation. Nevertheless, negotiation between these two perspectives fails during the dialogic interaction.

  19. NASA Earth Science Education Collaborative

    Science.gov (United States)

    Schwerin, T. G.; Callery, S.; Chambers, L. H.; Riebeek Kohl, H.; Taylor, J.; Martin, A. M.; Ferrell, T.

    2016-12-01

    The NASA Earth Science Education Collaborative (NESEC) is led by the Institute for Global Environmental Strategies with partners at three NASA Earth science Centers: Goddard Space Flight Center, Jet Propulsion Laboratory, and Langley Research Center. This cross-organization team enables the project to draw from the diverse skills, strengths, and expertise of each partner to develop fresh and innovative approaches for building pathways between NASA's Earth-related STEM assets to large, diverse audiences in order to enhance STEM teaching, learning and opportunities for learners throughout their lifetimes. These STEM assets include subject matter experts (scientists, engineers, and education specialists), science and engineering content, and authentic participatory and experiential opportunities. Specific project activities include authentic STEM experiences through NASA Earth science themed field campaigns and citizen science as part of international GLOBE program (for elementary and secondary school audiences) and GLOBE Observer (non-school audiences of all ages); direct connections to learners through innovative collaborations with partners like Odyssey of the Mind, an international creative problem-solving and design competition; and organizing thematic core content and strategically working with external partners and collaborators to adapt and disseminate core content to support the needs of education audiences (e.g., libraries and maker spaces, student research projects, etc.). A scaffolded evaluation is being conducted that 1) assesses processes and implementation, 2) answers formative evaluation questions in order to continuously improve the project; 3) monitors progress and 4) measures outcomes.

  20. The effectiveness of a head-heart-hands model for natural and environmental science learning in urban schools.

    Science.gov (United States)

    Jagannathan, Radha; Camasso, Michael J; Delacalle, Maia

    2018-02-01

    We describe an environmental and natural science program called Nurture thru Nature (NtN) that seeks to improve mathematics and science performance of students in disadvantaged communities, and to increase student interest in Science, Technology, Engineering and Mathematics (STEM) careers. The program draws conceptual guidance from the Head-Heart-Hands model that informs the current educational movement to foster environmental understanding and sustainability. Employing an experimental design and data from seven cohorts of students, we find some promising, albeit preliminary, indications that the program can increase students' science knowledge and grades in mathematics, science and language arts. We discuss the special adaptations that environmental and sustainability education programs need to incorporate if they are to be successful in today's resource depleted urban schools. Copyright © 2017 Elsevier Ltd. All rights reserved.

  1. Population Health Science: A Core Element of Health Science Education in Sub-Saharan Africa.

    Science.gov (United States)

    Hiatt, Robert A; Engmann, Natalie J; Ahmed, Mushtaq; Amarsi, Yasmin; Macharia, William M; Macfarlane, Sarah B; Ngugi, Anthony K; Rabbani, Fauziah; Walraven, Gijs; Armstrong, Robert W

    2017-04-01

    Sub-Saharan Africa suffers an inordinate burden of disease and does not have the numbers of suitably trained health care workers to address this challenge. New concepts in health sciences education are needed to offer alternatives to current training approaches.A perspective of integrated training in population health for undergraduate medical and nursing education is advanced, rather than continuing to take separate approaches for clinical and public health education. Population health science educates students in the social and environmental origins of disease, thus complementing disease-specific training and providing opportunities for learners to take the perspective of the community as a critical part of their education.Many of the recent initiatives in health science education in sub-Saharan Africa are reviewed, and two case studies of innovative change in undergraduate medical education are presented that begin to incorporate such population health thinking. The focus is on East Africa, one of the most rapidly growing economies in sub-Saharan Africa where opportunities for change in health science education are opening. The authors conclude that a focus on population health is a timely and effective way for enhancing training of health care professionals to reduce the burden of disease in sub-Saharan Africa.

  2. Science and students: Yucca Mountain project's education outreach program

    International Nuclear Information System (INIS)

    Gil, A.V.; Larkin, E.L.; Reilly, B.; Austin, P.

    1992-01-01

    The U.S. Department of Energy (DOE) is very concerned about the lack of understanding of basic science. Increasingly, critical decisions regarding the use of energy, technology, and the environment are being made. A well-educated and science-literate public is vital to the success of these decisions. Science education and school instruction are integral parts of the DOE's public outreach program on the Yucca Mountain Site Characterization Project (YMP). Project staff and scientists speak to elementary, junior high, high school, and university students, accepting all speaking invitations. The objectives of this outreach program include the following: (1) educating Nevada students about the concept of a high-level nuclear waste repository; (2) increasing awareness of energy and environmental issues; (3) helping students understand basic concepts of earth science and geology in relation to siting a potential repository; and (4) giving students information about careers in science and engineering

  3. Teaching Environmental Health Science for Informed Citizenship in the Science Classroom and Afterschool Clubs

    Science.gov (United States)

    Keselman, Alla; Levin, Daniel M.; Hundal, Savreen; Kramer, Judy F.; Matzkin, Karen; Dutcher, Gale

    2013-01-01

    In the era of growing concerns about human-induced climate change and sustainable development, it is important for the schools to prepare students for meaningful engagement with environmental policies that will determine the future of our society. To do this, educators need to face a number of challenges. These include deciding on the science knowledge and skills needed for informed citizenship, identifying teaching practices for fostering such knowledge and skills, and finding ways to implement new practices into the tightly packed existing curriculum. This paper describes two collaborative efforts between the U.S. National Library of Medicine (NLM) and University of Maryland College of Education that attempt to meet these challenges. The focus of both projects is on helping students develop information seeking and evaluation and argumentation skills, and applying them to complex socio-scientific issues that have bearing on students’ daily lives. The first effort involves co-designing an afterschool environmental health club curriculum with an interdisciplinary team of middle school teachers. The second effort is the development and implementation of a week-long school drinking water quality debate activity in a high school environmental science classroom. Both projects center on Tox Town, an NLM web resource that introduces students to environmental health issues in everyday environments. The paper describes successes and challenges of environmental health curriculum development, including teachers’ and researchers’ perception of contextual constraints in the club and classroom setting, tensions inherent in co-design, and students’ experience with socio-scientific argumentation. PMID:24382985

  4. Making the Connection between Environmental Science and Decision Making

    Science.gov (United States)

    Woodhouse, C. A.; Crimmins, M.; Ferguson, D. B.; Garfin, G. M.; Scott, C. A.

    2011-12-01

    As society is confronted with population growth, limited resources, and the impacts of climate variability and change, it is vital that institutions of higher education promote the development of professionals who can work with decision-makers to incorporate scientific information into environmental planning and management. Skills for the communication of science are essential, but equally important is the ability to understand decision-making contexts and engage with resource managers and policy makers. It is increasingly being recognized that people who understand the linkages between science and decision making are crucial if science is to better support planning and policy. A new graduate-level seminar, "Making the Connection between Environmental Science and Decision Making," is a core course for a new post-baccalaureate certificate program, Connecting Environmental Science and Decision Making at the University of Arizona. The goal of the course is to provide students with a basic understanding of the dynamics between scientists and decision makers that result in scientific information being incorporated into environmental planning, policy, and management decisions. Through readings from the environmental and social sciences, policy, and planning literature, the course explores concepts including scientific information supply and demand, boundary organizations, co-production of knowledge, platforms for engagement, and knowledge networks. Visiting speakers help students understand some of the challenges of incorporating scientific information into planning and decision making within institutional and political contexts. The course also includes practical aspects of two-way communication via written, oral, and graphical presentations as well as through the interview process to facilitate the transfer of scientific information to decision makers as well as to broader audiences. We aspire to help students develop techniques that improve communication and

  5. Pacific Northwest Laboratory annual report for 1992 to the DOE Office of Energy Research. Part 2, Environmental sciences

    Energy Technology Data Exchange (ETDEWEB)

    Grove, L.K. [ed.; Wildung, R.E.

    1993-03-01

    The 1992 Annual Report from Pacific Northwest Laboratory (PNL) to the US Department of Energy (DOE) describes research in environment and health conducted during fiscal year 1992. This report consists of four volumes oriented to particular segments of the PNL program, describing research performed for the DOE Office of Health and Environmental Research in the Office of Energy Research. The parts of the 1992 Annual Report are: Biomedical Sciences; Environmental Sciences; Atmospheric Sciences; and Physical Sciences. This Report is Part 2: Environmental Sciences. Included in this report are developments in Subsurface Science, Terrestrial Science, Laboratory-Directed Research and Development, Interactions with Educational Institutions, Technology Transfer, Publications, and Presentations. The research is directed toward developing a fundamental understanding of subsurface and terrestrial systems as a basis for both managing these critical resources and addressing environmental problems such as environmental restoration and global change. The Technology Transfer section of this report describes a number of examples in which fundamental research is laying the groundwork for the technology needed to resolve important environmental problems. The Interactions with Educational Institutions section of the report illustrates the results of a long-term, proactive program to make PNL facilities available for university and preuniversity education and to involve educational institutions in research programs. The areas under investigation include the effect of geochemical and physical phenomena on the diversity and function of microorganisms in deep subsurface environments, ways to address subsurface heterogeneity, and ways to determine the key biochemical and physiological pathways (and DNA markers) that control nutrient, water, and energy dynamics in arid ecosystems and the response of these systems to disturbance and climatic change.

  6. Modern Publishing Approach of Journal of Astronomy & Earth Sciences Education

    Science.gov (United States)

    Slater, Timothy F.

    2015-01-01

    Filling a needed scholarly publishing avenue for astronomy education researchers and earth science education researchers, the Journal of Astronomy & Earth Sciences Education - JAESE published its first volume and issue in 2014. The Journal of Astronomy & Earth Sciences Education - JAESE is a scholarly, peer-reviewed scientific journal publishing original discipline-based education research and evaluation, with an emphasis of significant scientific results derived from ethical observations and systematic experimentation in science education and evaluation. International in scope, JAESE aims to publish the highest quality and timely articles from discipline-based education research that advance understanding of astronomy and earth sciences education and are likely to have a significant impact on the discipline or on policy. Articles are solicited describing both (i) systematic science education research and (ii) evaluated teaching innovations across the broadly defined Earth & space sciences education, including the disciplines of astronomy, climate education, energy resource science, environmental science, geology, geography, agriculture, meteorology, planetary sciences, and oceanography education. The publishing model adopted for this new journal is open-access and articles appear online in GoogleScholar, ERIC, and are searchable in catalogs of 440,000 libraries that index online journals of its type. Rather than paid for by library subscriptions or by society membership dues, the annual budget is covered by page-charges paid by individual authors, their institutions, grants or donors: This approach is common in scientific journals, but is relatively uncommon in education journals. Authors retain their own copyright. The journal is owned by the Clute Institute of Denver, which owns and operates 17 scholarly journals and currently edited by former American Astronomical Society Education Officer Tim Slater, who is an endowed professor at the University of Wyoming and

  7. Relationship between Pre-School Preservice Teachers' Environmental Literacy and Science and Technology Literacy Self Efficacy Beliefs

    Science.gov (United States)

    Surmeli, Hikmet

    2013-01-01

    This study examined the relationship between preschool teachers' environmental literacy and their science and technology self efficacy beliefs. 120 preschool teachers from teacher education programme at one university participated in this study. Data were collected by using Environmental Literacy Scale and Science and Technology Literacy Self…

  8. Romanian - Swiss cooperative research programme "Environmental Science and Technology in Romania" (ESTROM)

    OpenAIRE

    PANIN, Nicolae; GIGER, Walter

    2008-01-01

    The Romanian Ministry for Education, Research and Youth (MECT), the Swiss Agency for Development and Cooperation (SDC) and the Swiss National Science Foundation had launched in 2004 the Romanian-Swiss research programme known as “Environmental Science and Technology in Romania” (ESTROM). ESTROM was established as a pilot programme of scientific co-operation between Swiss Research and Education Units with similar ones from Romania in the framework of SCOPES – a Swiss national programme for sup...

  9. Linking Science and Society With an Environmental Information Bridge

    Science.gov (United States)

    Welling, L.; Seielstad, G.; Jones, D.; Peterson, J.

    2001-12-01

    Building learning communities to engage the public in identifying and solving local and regional environmental problems is the vision of the newly created Northern Great Plains Center for People and the Environment at the University of North Dakota. The Center serves as an Environmental Information Bridge between science and society for citizens of the region, providing information, data, and value-added remote sensing products to precision agriculture, sustainable forestry, Native American land managers, and K-lifetime educators. Guided by the needs of end users, the new Center is a prototype for a national infrastructure that meets ESE's objective to "expand and accelerate the realization of economic and societal benefits from Earth science, information, and technology". The scientific community has been good at converting raw data into useful information. However, a serious communications gap exists between the communities of scientists and non-scientists. The new Center bridges this gap, creating a many-to-many exchange of information among those who learn first about the environment and those who will put those lessons to work for their economic welfare, the betterment of the quality of their lives, and the benefit of their descendants. A major outreach component of the Center, written and produced at UND, is Our Changing Planet, a public television series aimed at increasing viewers' awareness of environmental and climate change issues. Now carried by approximately 30 public television stations the series is distributed nationwide by the National Education Television Association. The Center has also recently established a partnership with StormCenter.com, LLC, a multimedia company and fellow partner in NASA's Federation of Earth Science Information Partners that uses leading-edge technology to deliver information about the environment to regional television stations. Service to the media provides a vital link between science and the public, as local weather

  10. The Value of Conceptual Models in Coping with Complexity and Interdisciplinarity in Environmental Sciences Education

    Science.gov (United States)

    Fortuin, Karen P. J.; van Koppen, C. S. A.; Leemans, Rik

    2011-01-01

    Conceptual models are useful for facing the challenges of environmental sciences curriculum and course developers and students. These challenges are inherent to the interdisciplinary and problem-oriented character of environmental sciences curricula. In this article, we review the merits of conceptual models in facing these challenges. These…

  11. An Investigation of the Goals for an Environmental Science Course: Teacher and Student Perspectives

    Science.gov (United States)

    Blatt, Erica N.

    2015-01-01

    This investigation uses an ethnographic case study approach to explore the benefits and challenges of including a variety of goals within a high school Environmental Science curriculum. The study focuses on environmental education (EE) goals established by the Belgrade Charter (1975), including developing students' environmental awareness and…

  12. The Effect of Environmental Science Projects on Students' Environmental Knowledge and Science Attitudes

    Science.gov (United States)

    Al-Balushi, Sulaiman M.; Al-Aamri, Shamsa S.

    2014-01-01

    The current study explores the effectiveness of involving students in environmental science projects for their environmental knowledge and attitudes towards science. The study design is a quasi-experimental pre-post control group design. The sample was 62 11th-grade female students studying at a public school in Oman. The sample was divided into…

  13. Heuristic principles to teach and learn boundary crossing skills in environmental science education

    NARCIS (Netherlands)

    Fortuin, K.P.J.

    2015-01-01

    Since the 1970s academic environmental science curricula have emerged all over the world addressing a wide range of topics and using knowledge from various disciplines. These curricula aim to deliver graduates with competencies to study, understand and address complex environmental problems.

  14. USGS Environmental health science strategy: providing environmental health science for a changing world: public review release

    Science.gov (United States)

    Bright, Patricia R.; Buxton, Herbert T.; Balistrieri, Laurie S.; Barber, Larry B.; Chapelle, Francis H.; Cross, Paul C.; Krabbenhoft, David P.; Plumlee, Geoffrey S.; Sleeman, Jonathan M.; Tillitt, Donald E.; Toccalino, Patricia L.; Winton, James R.

    2012-01-01

    America has an abundance of natural resources. We have bountiful clean water, fertile soil, and unrivaled national parks, wildlife refuges, and public lands. These resources enrich our lives and preserve our health and wellbeing. These resources have been maintained because of our history of respect for their value and an enduring commitment to their vigilant protection. Awareness of the social, economic, and personal value of the health of our environment is increasing. The emergence of environmentally driven diseases caused by environmental exposure to contaminants and pathogens is a growing concern worldwide. New health threats and patterns of established threats are affected by both natural and anthropogenic changes to the environment. Human activities are key drivers of emerging (new and re-emerging) health threats. Societal demands for land and natural resources, a better quality of life, improved economic prosperity, and the environmental impacts associated with these demands will continue to increase. Natural earth processes, climate trends, and related climatic events will add to the environmental impact of human activities. These environmental drivers will influence exposure to disease agents, including viral, bacterial, prion, and fungal pathogens, parasites, natural earth materials, toxins and other biogenic compounds, and synthetic chemicals and substances. The U.S. Geological Survey (USGS) defines environmental health science broadly as the interdisciplinary study of relations among the quality of the physical environment, the health of the living environment, and human health. The interactions among these three spheres are driven by human activities, ecological processes, and natural earth processes; the interactions affect exposure to contaminants and pathogens and the severity of environmentally driven diseases in animals and people. This definition provides USGS with a framework for synthesizing natural science information from across the Bureau

  15. Environmental programs for grades K-12 sponsored by the Westinghouse Waste Isolation Division Educational Programs Department

    International Nuclear Information System (INIS)

    Mikel, C.J.

    1993-01-01

    The Waste Isolation Pilot Plant (WIPP) created its educational programs department in 1990 as a result of the Secretary of Energy's focus on education stated in SEN-23-90. This Secretary of Energy Notice reflects the focus for US Department of Energy facilities to enhance education through their resources (both human and financial) with an emphasis on math and science. The mission of the Westinghouse Waste Isolation Division (WID) educational programs department is to enhance education at all levels and to promote educational experiences that give students the opportunity to make decisions and develop skills for productive lives. Programs have been developed around the environmental monitoring department, to give students from different grade levels hands on experiences in the environmental sciences field to stimulate their interest in the natural sciences

  16. Life sciences and environmental sciences

    Energy Technology Data Exchange (ETDEWEB)

    1992-02-01

    The DOE laboratories play a unique role in bringing multidisciplinary talents -- in biology, physics, chemistry, computer sciences, and engineering -- to bear on major problems in the life and environmental sciences. Specifically, the laboratories utilize these talents to fulfill OHER's mission of exploring and mitigating the health and environmental effects of energy use, and of developing health and medical applications of nuclear energy-related phenomena. At Lawrence Berkeley Laboratory (LBL) support of this mission is evident across the spectrum of OHER-sponsored research, especially in the broad areas of genomics, structural biology, basic cell and molecular biology, carcinogenesis, energy and environment, applications to biotechnology, and molecular, nuclear and radiation medicine. These research areas are briefly described.

  17. Life sciences and environmental sciences

    Energy Technology Data Exchange (ETDEWEB)

    1992-02-01

    The DOE laboratories play a unique role in bringing multidisciplinary talents -- in biology, physics, chemistry, computer sciences, and engineering -- to bear on major problems in the life and environmental sciences. Specifically, the laboratories utilize these talents to fulfill OHER`s mission of exploring and mitigating the health and environmental effects of energy use, and of developing health and medical applications of nuclear energy-related phenomena. At Lawrence Berkeley Laboratory (LBL) support of this mission is evident across the spectrum of OHER-sponsored research, especially in the broad areas of genomics, structural biology, basic cell and molecular biology, carcinogenesis, energy and environment, applications to biotechnology, and molecular, nuclear and radiation medicine. These research areas are briefly described.

  18. Extending the purposes of science education: addressing violence within socio-economic disadvantaged communities

    Science.gov (United States)

    Castano, Carolina

    2012-09-01

    Current discourses about science education show a wide concern towards humanisation and a more socio-cultural perspective of school science. They suggest that science education can serve diverse purposes and be responsive to social and environmental situations we currently face. However, these discourses and social approaches to science education tend to focus on global issues. They do not respond to the immediate needs and local context of some communities. I discuss in this paper why the purposes of science education need to be extended to respond to the local issue of violence. For this, I present a case study with a group of 38 students from a poor population in Bogotá, Colombia, located in one of the suburbs with highest levels of crime in the city. I examine the ways that science education contributes to and embodies its own forms of violence and explore how a new approach to science education could contribute to break the cycle of violence.

  19. Environmental Sciences Division. Annual progress report for period ending September 30, 1980. [Lead abstract

    Energy Technology Data Exchange (ETDEWEB)

    Auerbach, S.I.; Reichle, D.E.

    1981-03-01

    Research conducted in the Environmental Sciences Division for the Fiscal Year 1980 included studies carried out in the following Division programs and sections: (1) Advanced Fossil Energy Program, (2) Nuclear Program, (3) Environmental Impact Program, (4) Ecosystem Studies Program, (5) Low-Level Waste Research and Development Program, (6) National Low-Level Waste Program, (7) Aquatic Ecology Section, (8) Environmental Resources Section, (9) Earth Sciences Section, and (10) Terrestrial Ecology Section. In addition, Educational Activities and the dedication of the Oak Ridge National Environmental Research Park are reported. Separate abstracts were prepared for the 10 sections of this report.

  20. Investigation of Environmental Topics in the Science and Technology Curriculum and Textbooks in Terms of Environmental Ethics and Aesthetics

    Science.gov (United States)

    Lacin Simsek, Canan

    2011-01-01

    In order to solve environmental problems, it is thought that education should be connected with values. For this reason, it is emphasized that environmental issues should be integrated with ethical and aesthetic values. In this study, 6th, 7th and 8th grade science and technology curriculum and textbooks were investigated to find out how much…

  1. Resonance – Journal of Science Education | Indian Academy of ...

    Indian Academy of Sciences (India)

    Home; Journals; Resonance – Journal of Science Education; Volume 8; Issue 1. Lichens: A Valuable Bioresource for Environmental Monitoring and Sustainable Development. Hans Raj Negi. General Article Volume 8 Issue 1 January 2003 pp 51-58 ...

  2. Global Journal of Environmental Sciences

    African Journals Online (AJOL)

    Global Journal of Environmental Sciences is aimed at promoting research in all areas of Environmental Sciences including waste management, pollution control, and remediation of hazards. The journal is published twice a year. Visit the Global Journal Series website here: http://www.globaljournalseries.com/ ...

  3. Social and Economic Influences in Curriculum Change in Japan: Case History of Environmental Education.

    Science.gov (United States)

    Shimazu, Yasuo

    1981-01-01

    Surveys social, economic and environmental characteristics of Japan in the 1960s and 1970s and describes their influence on curriculum changes in secondary science education. Discusses Japanese attitudes towards nature as a foundation for environmental education, the impact of western culture on this attitude, and the future of environmental…

  4. Towards a truer multicultural science education: how whiteness impacts science education

    Science.gov (United States)

    Le, Paul T.; Matias, Cheryl E.

    2018-03-01

    The hope for multicultural, culturally competent, and diverse perspectives in science education falls short if theoretical considerations of whiteness are not entertained. Since whiteness is characterized as a hegemonic racial dominance that has become so natural it is almost invisible, this paper identifies how whiteness operates in science education such that it falls short of its goal for cultural diversity. Because literature in science education has yet to fully entertain whiteness ideology, this paper offers one of the first theoretical postulations. Drawing from the fields of education, legal studies, and sociology, this paper employs critical whiteness studies as both a theoretical lens and an analytic tool to re-interpret how whiteness might impact science education. Doing so allows the field to reconsider benign, routine, or normative practices and protocol that may influence how future scientists of Color experience the field. In sum, we seek to have the field consider the theoretical frames of whiteness and how it might influence how we engage in science education such that our hope for diversity never fully materializes.

  5. Pre-Service Teachers' Mind Maps and Opinions on STEM Education Implemented in an Environmental Literacy Course

    Science.gov (United States)

    Sümen, Özlem Özçakir; Çalisici, Hamza

    2016-01-01

    This study aims to implement a science, technology, engineering, and mathematics (STEM) education approach in an environmental education course. The research involved the design and implementation of STEM activities by researchers, as part of the environmental education course taught in the second year of a Primary School Teaching undergraduate…

  6. Evaluating a Graduate Professional Development Program for Informal Science Educators

    Science.gov (United States)

    Lake, Jeremy Paul

    This study is an examination and evaluation of the outcomes of a series of courses that I helped build to create a graduate certificate. Specifically, I wanted to evaluate whether or not the online iteration of the Informal Science Institutions Environmental Education Graduate Certificate Program truly provided the long term professional development needed to enhance the skills of the formal and informal educators participating so that they could contribute meaningfully to the improvement of science literacy in their respective communities. My role as an internal evaluator provided an extraordinary opportunity to know the intent of the learning opportunities and why they were constructed in a particular fashion. Through the combination of my skills, personal experiences both within the certificate's predecessor and as an educator, I was uniquely qualified to explore the outcomes of this program and evaluate its effectiveness in providing a long-term professional development for participants. After conducting a literature review that emphasized a need for greater scientific literacy in communities across America, it was evident that the formal education enterprise needs the support of informal educators working on the ground in myriad different settings in ways that provide science as both content and process, learning science facts and doing real science. Through a bridging of informal science educators with formal teachers, it was thought each could learn the culture of the other, making each more fluent in accessing community resources to help make these educators more collaborative and able to bridge the classroom with the outside world. This bridge promotes ongoing, lifelong learning, which in turn can help the national goal of greater scientific literacy. This study provided insight into the thinking involved in the learners' growth as they converted theory presented in course materials into practice. Through an iterative process of reviewing the course

  7. Environmental education. Umweltlernen. Veraenderungsmoeglichkeiten des Umweltbewusstseins

    Energy Technology Data Exchange (ETDEWEB)

    Fietkau, H.J.; Kessel, H.

    1981-01-01

    On the basis of findings of the social sciences as well as domestic and foreign experiences this reader shows how it might be possible to change the people's ecological awareness. After having given an introduction into a new approach of a model twelve authors discuss this topic from various fields of the social sciences (opinion poll research, pedagogics, sociology, psychology) and from practical fields (schools, adult education, commercial communication). Contributions to recent developments of environmental education in the Netherlands, Sweden and the United Kingdom supplement the volume. After having provided an evaluating summary the editors of the volume derive the practical consequences for changing the ecological awareness. First of all this is based on the results of opinion polls which point out that there is overall, a positive attitude towards pollution protection among the population of the F.R. of Germany. The citizens insist on increased activities for maintaining the environment both from governmental and non-governmental authorities, even if financial resources have to be employed. Opinion polls confirm that there is a basic preparedness to actively contribute, maintaining and improving the environment by people's own behaviour. As far as the corresponding attitudes are concerned the conditions for an environmentally-minded behaviour are given.

  8. Environmental education. Umweltlernen. Veraenderungsmoeglichkeiten des Umweltbewusstseins

    Energy Technology Data Exchange (ETDEWEB)

    Fietkau, H J; Kessel, H

    1981-01-01

    On the basis of findings of the social sciences as well as domestic and foreign experiences this reader shows how it might be possible to change the people's ecological awareness. After having given an introduction into a new approach of a model twelve authors discuss this topic from various fields of the social sciences (opinion poll research, pedagogics, sociology, psychology) and from practical fields (schools, adult education, commercial communication). Contributions to recent developments of environmental education in the Netherlands, Sweden and the United Kingdom supplement the volume. After having provided an evaluating summary the editors of the volume derive the practical consequences for changing the ecological awareness. First of all this is based on the results of opinion polls which point out that there is overall, a positive attitude towards pollution protection among the population of the F.R. of Germany. The citizens insist on increased activities for maintaining the environment both from governmental and non-governmental authorities, even if financial resources have to be employed. Opinion polls confirm that there is a basic preparedness to actively contribute, maintaining and improving the environment by people's own behaviour. As far as the corresponding attitudes are concerned the conditions for an environmentally-minded behaviour are given.

  9. Is Formal Environmental Education Friendly to Nature? Environmental Ethics in Science Textbooks for Primary School Pupils in Poland

    Science.gov (United States)

    Gola, Beata

    2017-01-01

    Due to the increased interest in ecology, global warming and numerous environmental problems, ecological issues are becoming extremely important in education. Many researchers and thinkers believe that solutions to environmental problems are affected by the environmental ethics adopted. This article identifies which of the three branches of…

  10. Strategies for Evaluating Complex Environmental Education Programs

    Science.gov (United States)

    Williams, V.

    2011-12-01

    Evidence for the effectiveness of environmental education programs has been difficult to establish for many reasons. Chief among them are the lack of clear program objectives and an inability to conceptualize how environmental education programs work. Both can lead to evaluations that make claims that are difficult to substantiate, such as significant changes in student achievement levels or behavioral changes based on acquisition of knowledge. Many of these challenges can be addressed by establishing the program theory and developing a logic model. However, claims of impact on larger societal outcomes are difficult to attribute solely to program activities. Contribution analysis may offer a promising method for addressing this challenge. Rather than attempt to definitively and causally link a program's activities to desired results, contribution analysis seeks to provide plausible evidence that can reduce uncertainty regarding the 'difference' a program is making to observed outcomes. It sets out to verify the theory of change behind a program and, at the same time, takes into consideration other influencing factors. Contribution analysis is useful in situations where the program is not experimental-there is little or no scope for varying how the program is implemented-and the program has been funded on the basis of a theory of change. In this paper, the author reviews the feasibility of using contribution analysis as a way of evaluating the impact of the GLOBE program, an environmental science and education program. Initially conceptualized by Al Gore in 1995, the program's implementation model is based on worldwide environmental monitoring by students and scientists around the globe. This paper will make a significant and timely contribution to the field of evaluation, and specifically environmental education evaluation by examining the usefulness of this analysis for developing evidence to assess the impact of environmental education programs.

  11. Framework for Reducing Teaching Challenges Relating to Improvisation of Science Education Equipment and Materials in Schools

    Science.gov (United States)

    Akuma, Fru Vitalis; Callaghan, Ronel

    2016-01-01

    The science education budget of many secondary schools has decreased, while shortages and environmental concerns linked to conventional Science Education Equipment and Materials (SEEMs) have emerged. Thus, in some schools, resourceful educators produce low-cost equipment from basic materials and use these so-called improvised SEEMs in practical…

  12. Fieldwork, Co-Teaching and Co-Generative Dialogue in Lower Secondary School Environmental Science

    Science.gov (United States)

    Rahmawati, Yuli; Koul, Rekha

    2016-01-01

    This article reports one of the case studies in a 3-year longitudinal study in environmental science education. This case explores the process of teaching about ecosystems through co-teaching and co-generative dialogue in a Year-9 science classroom in Western Australia. Combining with co-teaching and co-generative dialogue aimed at transforming…

  13. African Journals Online: Environmental Sciences

    African Journals Online (AJOL)

    Items 1 - 28 of 28 ... African Journals Online: Environmental Sciences ... Anthropology, Technology, Computer Science & Engineering, Veterinary Science ... and Metabolism (AJEM) is a biomedical peer-reviewed journal with international circulation. ... AFRREV STECH: An International Journal of Science and Technology.

  14. Environmental Management Science Program Workshop. Proceedings

    Energy Technology Data Exchange (ETDEWEB)

    None

    1998-07-01

    The Department of Energy Office of Environmental Management (EM), in partnership with the Office of Energy Research (ER), designed, developed, and implemented the Environmental Management Science Program as a basic research effort to fund the scientific and engineering understanding required to solve the most challenging technical problems facing the government's largest, most complex environmental cleanup program. The intent of the Environmental Management Science Program is to: (1) Provide scientific knowledge that will revolutionize technologies and cleanup approaches to significantly reduce future costs, schedules, and risks. (2) Bridge the gap between broad fundamental research that has wide-ranging applications such as that performed in the Department's Office of Energy Research and needs-driven applied technology development that is conducted in Environmental Management's Office of Science and Technology. (3) Focus the nation's science infrastructure on critical Department of Energy environmental problems. In an effort to share information regarding basic research efforts being funded by the Environmental Management Science Program and the Environmental Management/Energy Research Pilot Collaborative Research Program (Wolf-Broido Program), this CD includes summaries for each project. These project summaries, available in portable document format (PDF), were prepared in the spring of 1998 by the principal investigators and provide information about their most recent project activities and accomplishments.

  15. Science education through informal education

    Science.gov (United States)

    Kim, Mijung; Dopico, Eduardo

    2016-06-01

    To develop the pedagogic efficiency of informal education in science teaching, promoting a close cooperation between institutions is suggested by Monteiro, Janerine, de Carvalho, and Martins. In their article, they point out effective examples of how teachers and educators work together to develop programs and activities at informal education places such as science museums. Their study explored and discussed the viability and relevancy of school visits to museums and possibilities to enhance the connection between students' visits in informal contexts and their learning in schools. Given that students learn science by crossing the boundaries of formal and informal learning contexts, it is critical to examine ways of integrated and collaborative approach to develop scientific literacy to help students think, act and communicate as members of problem solving communities. In this forum, we suggest the importance of students' lifeworld contexts in informal learning places as continuum of Monteiro, Janerine, de Carvalho, and Martins' discussion on enhancing the effectiveness of informal learning places in science education.

  16. Does science education need the history of science?

    Science.gov (United States)

    Gooday, Graeme; Lynch, John M; Wilson, Kenneth G; Barsky, Constance K

    2008-06-01

    This essay argues that science education can gain from close engagement with the history of science both in the training of prospective vocational scientists and in educating the broader public about the nature of science. First it shows how historicizing science in the classroom can improve the pedagogical experience of science students and might even help them turn into more effective professional practitioners of science. Then it examines how historians of science can support the scientific education of the general public at a time when debates over "intelligent design" are raising major questions over the kind of science that ought to be available to children in their school curricula. It concludes by considering further work that might be undertaken to show how history of science could be of more general educational interest and utility, well beyond the closed academic domains in which historians of science typically operate.

  17. Career education attitudes and practices of K-12 science educators

    Science.gov (United States)

    Smith, Walter S.

    A random sample of 400 K-12 science educators who were members of the National Science Teachers Association were surveyed regarding their attitude toward and practice of career education in their science teaching. These science teachers rejected a narrowly vocational view, favoring instead a conception of career education which included self-perception, values analysis, and vocational skills objectives. The science educators affirmed the importance of career education for a student's education, asserted career education ought to be taught in their existing science courses, and expressed a willingness to do so. Fewer than one-third of the science teachers, however, reported incorporating career education at least on a weekly basis in their science lessons. The major impediment to including more career education in science teaching was seen to be their lack of knowledge of methods and materials relevant to science career education, rather than objections from students, parents, or administrators; their unwillingness; or their evaluation of career education as unimportant. Thus, in order to improve this aspect of science teaching, science teachers need more concrete information about science career education applications.

  18. Environmental Education and Small Business Environmental Activity

    Science.gov (United States)

    Redmond, Janice; Walker, Beth

    2011-01-01

    Environmental education is seen as a key driver of small business environmental management, yet little is known about the activities small business owner-managers are undertaking to reduce their environmental impact or in what areas they may need education. Therefore, research that can identify environmental management activities being undertaken…

  19. More than a Museum: Natural History is Relevant in 21st Century Environmental Science

    Science.gov (United States)

    Hernandez, R. R.; Murphy-Mariscal, M. L.; Barrows, C. W.

    2015-12-01

    In the Anthropocene, the relevancy of natural history in environmental science is challenged and marginalized today more than ever. We tested the hypothesis that natural history is relevant to the fields of environmental science and ecology by assessing the values, needs, and decisions related to natural history of graduate students and environmental science professionals across 31 universities and various employers, respectively, in California. Graduate students surveyed (93.3%) agreed that natural history was relevant to science, approximately 70% believed it "essential" for conducting field-based research; however, 54.2% felt inadequately trained to teach a natural history course and would benefit from additional training in natural history (> 80%). Of the 185 professionals surveyed, all felt that natural history was relevant to science and "essential" or "desirable" in their vocation (93%). Our results indicate a disconnect between the value and relevancy of natural history in 21st century ecological science and opportunities for gaining those skills and knowledge through education and training.

  20. Proceedings of the 6. Banska Stiavnica Days 2004. Environmental impacts on the environment. Trends in environmental sciences and radio-environmental sciences

    International Nuclear Information System (INIS)

    Hybler, P.; Maruskova, A.

    2004-12-01

    Scientific conference deals with problems in environmental sciences and radio-environmental sciences. The conference proceeded in two sections: (A) Environmental engineering, (B) Nuclear technologies. Sixty registered people and fifty guests participated on this conference. Twenty-seven presentations and eleven posters were presented. Proceedings contain twenty-six papers from which fourteen papers deal with the scope of INIS

  1. Environmental science and technology

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2008-07-01

    The environmental Science and Technology Program was structured based on the continuous growth of environmental activities on areas related to nuclear programs at IPEN. The program comprehends five main areas: Environmental analysis: Chemical technology; Polymer technology nucleus: Chemical and Isotope characterization and Analytical Chemistry for the Nuclear Fuel Cycle samples.

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

    Science.gov (United States)

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

    2008-12-01

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

  3. Science and the city: A visual journey towards a critical place based science education

    Science.gov (United States)

    Ibrahim, Sheliza

    The inclusion of societal and environmental considerations during the teaching and learning of science and technology has been a central focus among science educators for many decades. Major initiatives in science and technology curriculum advocate for science, technology, society and environment (STSE). Yet, it is surprising that despite these longstanding discussions, it is only recently that a handful of researchers have turned to students' 'places' (and the literature of place based education) to serve as a source of teaching and learning in science education. In my study, I explore three issues evident in place based science education. First, it seems that past scholarship focused on place-based projects which explore issues usually proposed by government initiatives, university affiliation, or community organizations. Second, some of the studies fail to pay extended attention to the collaborative and intergenerational agency that occurs between researcher, teacher, student, and community member dynamics, nor does it share the participatory action research process in order to understand how teacher practice, student learning, and researcher/local collaborations might help pedagogy emerge. The third issue is that past place-based projects, rarely if ever, return to the projects to remember the collaborative efforts and question what aspects sustained after they were complete. To address these issues, I propose a critical place based science education (CPBSE) model. I describe a participatory action research project that develops and explores the CPBSE model. The data were gathered collaboratively among teachers, researchers, and students over 3 years (2006-2008), via digital video ethnography, photographs, and written reflections. The data were analysed using a case study approach and the constant comparative method. I discuss the implications for its practice in the field of STSE and place based education. I conclude that an effective pedagogical model of

  4. Fermilab Friends for Science Education | Welcome

    Science.gov (United States)

    Fermilab Friends for Science Education FFSE Home About Us Join Us Support Us Contact Us Fermilab Friends for Science Education photo Fermilab Friends for Science Education supports innovative science education programs at Fermilab. Its mission is to: Enhance the quality of precollege science education in

  5. Integration and timing of basic and clinical sciences education.

    Science.gov (United States)

    Bandiera, Glen; Boucher, Andree; Neville, Alan; Kuper, Ayelet; Hodges, Brian

    2013-05-01

    Medical education has traditionally been compartmentalized into basic and clinical sciences, with the latter being viewed as the skillful application of the former. Over time, the relevance of basic sciences has become defined by their role in supporting clinical problem solving rather than being, of themselves, a defining knowledge base of physicians. As part of the national Future of Medical Education in Canada (FMEC MD) project, a comprehensive empirical environmental scan identified the timing and integration of basic sciences as a key pressing issue for medical education. Using the literature review, key informant interviews, stakeholder meetings, and subsequent consultation forums from the FMEC project, this paper details the empirical basis for focusing on the role of basic science, the evidentiary foundations for current practices, and the implications for medical education. Despite a dearth of definitive relevant studies, opinions about how best to integrate the sciences remain strong. Resource allocation, political power, educational philosophy, and the shift from a knowledge-based to a problem-solving profession all influence the debate. There was little disagreement that both sciences are important, that many traditional models emphasized deep understanding of limited basic science disciplines at the expense of other relevant content such as social sciences, or that teaching the sciences contemporaneously rather than sequentially has theoretical and practical merit. Innovations in integrated curriculum design have occurred internationally. Less clear are the appropriate balance of the sciences, the best integration model, and solutions to the political and practical challenges of integrated curricula. New curricula tend to emphasize integration, development of more diverse physician competencies, and preparation of physicians to adapt to evolving technology and patients' expectations. Refocusing the basic/clinical dichotomy to a foundational

  6. Research Experience for Undergraduates Program in Multidisciplinary Environmental Science

    Science.gov (United States)

    Wu, M. S.

    2012-12-01

    During summers 2011 and 12 Montclair State University hosted a Research Experience for Undergraduates Program (REU) in transdisciplinary, hands-on, field-oriented research in environmental sciences. Participants were housed at the Montclair State University's field station situated in the middle of 30,000 acres of mature forest, mountain ridges and freshwater streams and lakes within the Kittatinny Mountains of Northwest New Jersey, Program emphases were placed on development of project planning skills, analytical skills, creativity, critical thinking and scientific report preparation. Ten students were recruited in spring with special focus on recruiting students from underrepresented groups and community colleges. Students were matched with their individual research interests including hydrology, erosion and sedimentation, environmental chemistry, and ecology. In addition to research activities, lectures, educational and recreational field trips, and discussion on environmental ethics and social justice played an important part of the program. The ultimate goal of the program is to facilitate participants' professional growth and to stimulate the participants' interests in pursuing Earth Science as the future career of the participants.

  7. Games in Science Education

    DEFF Research Database (Denmark)

    Magnussen, Rikke

    2014-01-01

    , 2007). Some of these newer formats are developed in partnerships between research and education institutions and game developers and are based on learning theory as well as game design methods. Games well suited for creating narrative framework or simulations where students gain first-hand experience......This paper presents a categorisation of science game formats in relation to the educational possibilities or limitations they offer in science education. This includes discussion of new types of science game formats and gamification of science. Teaching with the use of games and simulations...... in science education dates back to the 1970s and early 80s were the potentials of games and simulations was discussed extensively as the new teaching tool ( Ellington et al. , 1981). In the early 90s the first ITC -based games for exploration of science and technical subjects was developed (Egenfeldt...

  8. Hip-Hop, Social Justice, and Environmental Education: Toward a Critical Ecological Literacy

    Science.gov (United States)

    Cermak, Michael J.

    2012-01-01

    This essay describes an educational initiative that used environmentally themed (green) hip-hop to stimulate learning in an environmental science classroom. Students were then challenged to compose their own green hip-hop and their lyrics demonstrated skills that have thematic consistency around what is called a Critical Ecological Literacy (CEL).…

  9. An Analysis of the Interdisciplinarity Theme in the Main Brazilian Journals on Science Education

    Directory of Open Access Journals (Sweden)

    Guilherme do Amaral Carneiro

    2018-01-01

    Full Text Available The discussion on interdisciplinarity has been present in the scope of Education for over 30 years and has had repercussions in the area of Science Education. Despite the many works in the main Brazilian journals in the area, there are still gaps about complementary information on research that relates interdisciplinarity and Science Education. In order to fill some of this gap, we carried out a study whose objective was to identify these approaches in articles of the main national science education journals. We use the terms interdisciplinarity and interdisciplinary as descriptors in the titles, abstracts, and keywords to select the articles analyzed. It was found that studies focus on basic education and deal mainly with curriculum issues. The areas of physics and biology education stand out, as well as the science environment technology society and Environmental Education approaches. Data also point to a contrasting panorama, of diversification and decrease of the research that relates Science Teaching and Interdisciplinarity.

  10. Publishing in the Refereed International Journal of Astronomy & Earth Sciences Education JAESE

    Science.gov (United States)

    Slater, Timothy F.

    2015-08-01

    Filling a needed scholarly publishing avenue for astronomy education researchers and earth science education researchers, the Journal of Astronomy & Earth Sciences Education- JAESE was first published in 2014. JAESE is a scholarly, peer-reviewed scientific journal publishing original discipline-based education research and evaluation, with an emphasis of significant scientific results derived from ethical observations and systematic experimentation in science education and evaluation. International in scope, JAESE aims to publish the highest quality and timely articles from discipline-based education research that advance understanding of astronomy and earth sciences education and are likely to have a significant impact on the discipline or on policy. Articles are solicited describing both (i) systematic science education research and (ii) evaluated teaching innovations across the broadly defined Earth & space sciences education, including the disciplines of astronomy, climate education, energy resource science, environmental science, geology, geography, agriculture, meteorology, planetary sciences, and oceanography education. The publishing model adopted for this new journal is open-access and articles appear online in GoogleScholar, ERIC, EBSCO, ProQuest, and NASA SAO/ADS and are searchable in catalogs of 440,000 libraries that index online journals of its type. Rather than paid for by library subscriptions or by society membership dues, the annual budget is covered by page-charges paid by individual authors, their institutions, grants or donors: This approach is common in scientific journals, but is relatively uncommon in education journals. Authors retain their own copyright. The journal is owned by the Clute Institute in the United States, which owns and operates 17 scholarly journals and currently edited by former American Astronomical Society Education Officer Tim Slater, who is an endowed professor at the University of Wyoming and a Senior Scientist at the

  11. Science Theatre as dissemination of environmental awareness

    DEFF Research Database (Denmark)

    Chemi, Tatiana; Kastberg, Peter

    2015-01-01

    hides behind this label? Is this concept at all new? The purpose of this article is threefold: 1) to describe Science Theatre in terms of typology with specific focus on environmental subjects, 2) to address Science Theatre as a borderline meeting place (agora or arena) between science and theatre 3......A community project with the intention of developing specific communication on environmental issues for children age 3-7 allies with a theatre artist and storyteller. The result is a meeting between science and theatre. Theatre, with its borderline praxis between entertainment and reflection...... offered a precious opportunity to deliver difficult scientific or social issues within the environmental mindset to such youngsters, an opportunity well exploited and well received. But what makes Science Theatre an obvious choice in order to communicate natural sciences or environmental issues? What...

  12. A Longitudinal Study of Environmental and Outdoor Education: A Cultural Change

    Science.gov (United States)

    Tal, Tali; Morag, Orly

    2013-01-01

    In this case-study, we present a longitudinal study of one elementary (grades 1-6) school's environmental education (EE) in order to understand the ways in which the school culture supports outdoor EE as a critical component of their science education program. The school, which was known for its school-based EE curriculum that encompasses an…

  13. Epistemic agency in an environmental sciences watershed investigation fostered by digital photography

    Science.gov (United States)

    Zimmerman, Heather Toomey; Weible, Jennifer L.

    2018-05-01

    This collective case study investigates the role of digital photography to support high school students' engagement in science inquiry practices during a three-week environmental sciences unit. The study's theoretical framework brings together research from digital photography, participation in environmental science practices, and epistemic agency. Data analysed include field notes and video transcripts from two groups of learners (n = 19) that focus on how high school students used digital photography during their participation in two distinct environmental monitoring practices: stream mapping and macroinvertebrate identification. Our study resulted in two findings related to the role of digital photography where students developed knowledge as they engaged in environmental monitoring inquiry practices. First, we found that digital photography was integral to the youths' epistemic agency (defined as their confidence that they could build knowledge related to science in their community) as they engaged in data collection, documenting environmental monitoring procedures, and sharing data in the classroom. Based this finding, an implication of our work is a refined view of the role of digital photography in environmental sciences education where the use of photography enhances epistemic agency in inquiry-based activities. Second, we found that the youths innovated a use of digital photography to foster a recognition that they were capable and competent in scientific procedures during a streamside study. Based on this finding, we offer a theoretical implication that expands the construct of epistemic agency; we posit that epistemic agency includes a subcomponent where the students purposefully formulate an external recognition as producers of scientific knowledge.

  14. Globalization and Science Education

    Science.gov (United States)

    Bencze, J. Lawrence; Carter, Lyn; Chiu, Mei-Hung; Duit, Reinders; Martin, Sonya; Siry, Christina; Krajcik, Joseph; Shin, Namsoo; Choi, Kyunghee; Lee, Hyunju; Kim, Sung-Won

    2013-06-01

    Processes of globalization have played a major role in economic and cultural change worldwide. More recently, there is a growing literature on rethinking science education research and development from the perspective of globalization. This paper provides a critical overview of the state and future development of science education research from the perspective of globalization. Two facets are given major attention. First, the further development of science education as an international research domain is critically analyzed. It seems that there is a predominance of researchers stemming from countries in which English is the native language or at least a major working language. Second, the significance of rethinking the currently dominant variants of science instruction from the perspectives of economic and cultural globalization is given major attention. On the one hand, it is argued that processes concerning globalization of science education as a research domain need to take into account the richness of the different cultures of science education around the world. At the same time, it is essential to develop ways of science instruction that make students aware of the various advantages, challenges and problems of international economic and cultural globalization.

  15. Leaving the Classroom: A Didactic Framework for Education in Environmental Sciences

    Science.gov (United States)

    Dopico, Eduardo; Garcia-Vazquez, Eva

    2011-01-01

    In Continuous Education curricula in Spain, the programs on sciences of the environment are aimed toward understandings of sustainability. Teaching practice rarely leaves the classroom for outdoor field studies. At the same time, teaching practice is generally focused on examples of how human activities are harmful for ecosystems. From a pedagogic…

  16. Software support for environmental measurement in quality at educational institutions

    Directory of Open Access Journals (Sweden)

    Alena Pauliková

    2016-03-01

    Full Text Available The analysed theme of this article is based on the training of environmental measurements for workplaces. This is very important for sustainable quality in technical educational institutions. Applied kinds of software, which are taught at technical educational institutions, have to offer the professional and methodical knowledge concerning conditions of working ambient for students of selected technical specialisations. This skill is performed in such a way that the graduates, after entering the practical professional life, will be able to participate in solutions for actual problems that are related to environmental protection by means of software support. Nowadays, during the training processit is also obligatory to introduce technical science. Taking into consideration the above-mentioned facts it is possible to say that information technology support for environmental study subjects is a relevant aspect, which should be integrated into the university educational process. There is an effective progress that further highlights the focus on the quality of university education not only for environmental engineers. Actual trends require an increasing number of software/hardware educated engineers who can participate in qualitative university preparation, i.e.IT environmentalists. The Department of Environmental Engineering at the Faculty of Mechanical Engineering, TechnicalUniversity in Košice, Slovakia is an institution specified and intended for quality objectivisation. This institution introduced into the study programmes (“Environmental Management” and “Technology of Environmental Protection” study subjects with the software support, which are oriented towards outdoor and indoor ambient and in this way the Department of Process and Environmental Engineering is integrated effectively and intensively into the area of measurement training with regard to the requirement of quality educational processes.

  17. ''Brain-science and education''. Towards human security and well-being

    International Nuclear Information System (INIS)

    Koizumi, Hideaki

    2005-01-01

    This lecture discusses concepts of learning and education that have been expressed in terms of the viewpoint of natural science, and proposes a new way of studying learning and education based on functional brain imaging such as fMRI, MEG, and OT (Optical Topography). From a biological viewpoint, they are related to brain development because the brain is an adaptable information processor that is open to environmental stimuli. Stimuli cause new neuronal connections to form, which allow better adaptation to the environment. Thus, education should be designed to guide and inspire the construction of the basic architecture for information processing in the brain by preparing and controlling the input stimuli given to the learners. Education is the process in which learning is guided to provide an optimal environment. This new approach to study of learning and education is called brain science and education.'' (S. Ohno)

  18. Scientific knowledge and environmental policy. Why science needs values. Environmental essay

    Energy Technology Data Exchange (ETDEWEB)

    Carolan, M.S. [Department of Sociology, Colorado State University, Fort Collins (United States)

    2006-12-15

    While the term 'science' is evoked with immense frequency in the political arena, it continues to be misunderstood. Perhaps the most repeated example of this - particularly when dealing with environmental policy and regulatory issues - is when science is called upon to provide the unattainable: namely, proof. What is scientific knowledge and, more importantly, what is it capable of providing us? These questions must be answered - by policymakers, politicians, the public, and scientists themselves - if we hope to ever resolve today's environmental controversies in a just and equitable way. This paper begins by critically examining the concepts of uncertainty and proof as they apply to science. Discussion then turns to the issue of values in science. This is to speak of the normative decisions that are made routinely in the environmental sciences (but often without them being recognized as such). To conclude, insights are gleaned from the preceding sections to help us understand how science should be utilized and conducted, particularly as it applies to environmental policy.

  19. Towards Eco-reflexive Science Education. A Critical Reflection About Educational Implications of Green Chemistry

    Science.gov (United States)

    Sjöström, Jesper; Eilks, Ingo; Zuin, Vânia G.

    2016-05-01

    The modern world can be described as a globalized risk society. It is characterized by increasing complexity, unpredictable consequences of techno-scientific innovations and production, and its environmental consequences. Therefore, chemistry, just like many other knowledge areas, is in an ongoing process of environmentalization. For example, green chemistry has emerged as a new chemical metadiscipline and movement. The philosophy of green chemistry was originally based on a suggestion of twelve principles for environment-friendly chemistry research and production. The present article problematizes limitations in green chemistry when it comes to education. It argues that the philosophy of green chemistry in the context of education needs to be extended with socio-critical perspectives to form educated professionals and citizens who are able to understand the complexity of the world, to make value-based decisions, and to become able to engage more thoroughly in democratic decision-making on sustainability issues. Different versions of sustainability-oriented science/chemistry education are discussed to sharpen a focus on the most complex type, which is Bildung-oriented, focusing emancipation and leading to eco-reflexive education. The term eco- reflexive is used for a problematizing stance towards the modern risk society, an understanding of the complexity of life and society and their interactions, and a responsibility for individual and collective actions towards socio-ecojustice and global sustainability. The philosophical foundation and characteristics of eco-reflexive science education are sketched on in the article.

  20. Environmental Consumerism in the United Kingdom: Some Reflections on Managerial Responses and Educational Needs.

    Science.gov (United States)

    Dillon, P. J.; Jones, E. L.

    1996-01-01

    In England, management policies on land use and environmental consumerism are demand led, reactive, and detached from ecological and economic realities. Education that emphasizes environmental management from a standpoint of ethics, economics, political science, and law is recommended. (SK)

  1. Is Religious Education Compatible with Science Education?

    Science.gov (United States)

    Mahner, Martin; Bunge, Mario

    1996-01-01

    Addresses the problem of the compatibility of science and religion, and its bearing on science and religious education, challenges the popular view that science and religion are compatible or complementary. Discusses differences at the doctrinal, metaphysical, methodological, and attitudinal levels. Argues that religious education should be kept…

  2. Statistics for environmental science and management

    National Research Council Canada - National Science Library

    Manly, B.F.J

    2009-01-01

    .... Additional topics covered include environmental monitoring, impact assessment, censored data, environmental sampling, the role of statistics in environmental science, assessing site reclamation...

  3. Science Teaching in Science Education

    Science.gov (United States)

    Callahan, Brendan E.; Dopico, Eduardo

    2016-01-01

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

  4. Open source hardware solutions for low-cost, do-it-yourself environmental monitoring, citizen science, and STEM education

    Science.gov (United States)

    Hicks, S. D.; Aufdenkampe, A. K.; Horsburgh, J. S.; Arscott, D. B.; Muenz, T.; Bressler, D. W.

    2016-12-01

    The explosion in DIY open-source hardware and software has resulted in the development of affordable and accessible technologies, like drones and weather stations, that can greatly assist the general public in monitoring environmental health and its degradation. It is widely recognized that education and support of audiences in pursuit of STEM literacy and the application of emerging technologies is a challenge for the future of citizen science and for preparing high school graduates to be actively engaged in environmental stewardship. It is also clear that detecting environmental change/degradation over time and space will be greatly enhanced with expanded use of networked, remote monitoring technologies by watershed organizations and citizen scientists if data collection and reporting are properly carried out and curated. However, there are few focused efforts to link citizen scientists and school programs with these emerging tools. We have started a multi-year program to develop hardware and teaching materials for training students and citizen scientists about the use of open source hardware in environmental monitoring. Scientists and educators around the world have started building their own dataloggers and devices using a variety of boards based on open source electronics. This new hardware is now providing researchers with an inexpensive alternative to commercial data logging and transmission hardware. We will present a variety of hardware solutions using the Arduino-compatible EnviroDIY Mayfly board (http://envirodiy.org/mayfly) that can be used to build and deploy a rugged environmental monitoring station using a wide variety of sensors and options, giving the users a fully customizable device for making measurements almost anywhere. A database and visualization system is being developed that will allow the users to view and manage the data their devices are collecting. We will also present our plan for developing curricula and leading workshops to various

  5. Melding Environmental Education and Creative Learning in Elementary and Middle-school Settings

    Science.gov (United States)

    Jain, S.; Baker, T.; Crofton-Macdonald, J.; Scott, M.

    2017-12-01

    Teaching environmental topics, such as sustainability and ecosystem management, to students through the lens of computational thinking provides unique educational opportunities. Environmental topics are an excellent source for multidisciplinary learning, as questions concerning human well-being, environmental policy, science, and mathematics can naturally be incorporated into educational discussions and activities. The use of computational modeling allows students to critically reason about and explore environmental concepts by envisioning complexity, and asking and investigating a series of "what if" questions. Students can furthermore reflect on their own relationship with their local ecology. For the past five years, we have tested and developed activities for middle school students. Through in-class activities, workshop, and summer clubs, we have explored these ideas. We plan to present examples from our work and a tentative framework for a new approach to environmental education, one reinforced by computational thinking and creative learning.

  6. Safety Education and Science.

    Science.gov (United States)

    Ralph, Richard

    1980-01-01

    Safety education in the science classroom is discussed, including the beginning of safe management, attitudes toward safety education, laboratory assistants, chemical and health regulation, safety aids, and a case study of a high school science laboratory. Suggestions for safety codes for science teachers, student behavior, and laboratory…

  7. Science and Public Understanding: The Role of the Historian of Education

    Science.gov (United States)

    Watts, Ruth

    2017-01-01

    In this article, questions of public education in both environmental issues and science, more broadly, are examined in an effort to respond to Richard Aldrich's call for historians of education to use their skills and understanding both to inform the present and to shape a more enlightened future. In particular, the lives and work of three women…

  8. Understanding leadership in the environmental sciences

    Directory of Open Access Journals (Sweden)

    Louisa S. Evans

    2015-03-01

    Full Text Available Leadership is often assumed, intuitively, to be an important driver of sustainable development. To understand how leadership is conceptualized and analyzed in the environmental sciences and to discover what this research says about leadership outcomes, we conducted a review of environmental leadership research over the last 10 years. We found that much of the environmental leadership literature focuses on a few key individuals and desirable leadership competencies. The literature also reports that leadership is one of the most important of a number of factors contributing to effective environmental governance. Only a subset of the literature highlights interacting sources of leadership, disaggregates leadership outcomes, or evaluates leadership processes in detail. We argue that the literature on environmental leadership is highly normative. Leadership is typically depicted as an unequivocal good, and its importance is often asserted rather than tested. We trace how leadership studies in the management sciences are evolving and argue that, taking into account the state of the art in environmental leadership research, more critical approaches to leadership research in environmental science can be developed.

  9. Teaching Environmental Education through PBL: Evaluation of a Teaching Intervention Program

    Science.gov (United States)

    Vasconcelos, Clara

    2012-04-01

    If our chosen aim in science education is to be inclusive and to improve students' learning achievements, then we must identify teaching methodologies that are appropriate for teaching and learning specific knowledge. Karagiorgi and Symeo 2005) remind us that instructional designers are thus challenged to translate the philosophy of constructivism into current practice. Thus, research in science education must focus on evaluating intervention programs which ensure the effective construction of knowledge and development of competencies. The present study reports the elaboration, application and evaluation of a problem-based learning (PBL) program with the aim of examining its effectiveness with students learning Environmental Education. Prior research on both PBL and Environmental Education (EE) was conducted within the context of science education so as to elaborate and construct the intervention program. Findings from these studies indicated both the PBL methodology and EE as helpful for teachers and students. PBL methodology has been adopted in this study since it is logically incorporated in a constructivism philosophy application (Hendry et al. 1999) and it was expected that this approach would assist students towards achieving a specific set of competencies (Engel 1997). On the other hand, EE has evolved at a rapid pace within many countries in the new millennium (Hart 2007), unlike any other educational area. However, many authors still appear to believe that schools are failing to prepare students adequately in EE (Walsche 2008; Winter 2007). The following section describes the research that was conducted in both areas so as to devise the intervention program.

  10. Nuclear science education in Taiwan, 1956-1992

    International Nuclear Information System (INIS)

    Chung Chien

    1993-01-01

    The nuclear science education has been established in Taiwan at the College of Nuclear Science, National Tsing Hua University since 1956, the only one among 123 universities and colleges in Taiwan where nuclear-related education is offered. The Nuclear/Radiochemistry program, with nine faculty members, offers bachelor's, master's, and doctorate degrees in Nuclear Science. Lectures and lab classes of nuclear chemistry, radiochemistry, and allied branches in health physics, nuclear instruments, nuclear engineering, nuclear medicine, radiation biology, and environmental monitoring are given to the 17 undergraduate students and 33 postgraduate students currently registered. Support from the well-developed local nuclear power industry and government agencies is converged with rapid growth rate toward the Nuclear/Radiochemistry program; the 1992 annual research contracts for the program amounted over one million US dollars. Careerplacement program for graduates is developed to orientate them into the local nuclear power utilities as well as agricultural, medical, industrial, academic, and governmental sects where nuclear chemists and radiochemists at all levels are desperately needed. (author) 8 refs.; 3 figs.; 4 tabs

  11. Center for Environmental Health Sciences

    Data.gov (United States)

    Federal Laboratory Consortium — The primary research objective of the Center for Environmental Health Sciences (CEHS) at the University of Montana is to advance knowledge of environmental impacts...

  12. Is Christian Education Compatible With Science Education?

    Science.gov (United States)

    Martin, Michael

    Science education and Christian education are not compatible if by Christian education one means teaching someone to be a Christian. One goal of science education is to give students factual knowledge. Even when there is no actual conflict of this knowledge with the dogmas of Christianity, there exists the potential for conflict. Another goal of science education is to teach students to have the propensity to be sensitive to evidence: to hold beliefs tentatively in light of evidence and to reject these beliefs in the light of new evidence if rejection is warranted by this evidence. This propensity conflicts with one way in which beliefs are often taught in Christian education: namely as fundamental dogmas, rather than as subject to revision in the light of the evidence.

  13. "Nuestra Tierra Dinamica" Global Climate Change STEM Education Fostering Environmental Stewardship

    Science.gov (United States)

    La Grave, M.; de Valenzuela, M.; Russell, R.

    2012-12-01

    CLUB ECO LÓGICO is a democratic and participatory program that provides active citizenship in schools and community, placing climate change into context for the Latino Community. The program's objectives focus on: 1. The Environment. Reducing the school and community impact on the environment through environmental footprint through stewardship actions. 2. Empowerment. Engaging participants through project and service learning and make decisions about how to improve their schools, their homes and their community's environment. 3. Community and Research Partnerships. Fostering collaborations with local community, stakeholders, government, universities, research organizations, and businesses that have expertise in environmental research, management, education and climate change. 4. Awareness. Increasing environmental and climate science knowledge of participants through STEM activities and hands-on access to technology. 5. Research and evaluation. Assessing the relevance of program activities through the engagement of the Latino community in planning and the effectiveness and impact of STEM activities through formative and summative evaluation. To address these objectives, the program has several inter related components in an after school setting: SUN EARTH Connections: Elementary (grades K to 2) students learn the basic climate change concepts through inquiry and hands on STEM activities. Bilingual 8 facilitators adapt relevant NASA educational resources for use in inquiry based, hands on activities. Drama and the arts provide unique experiences as well as play a key role in learning, participation and facilitation. GREEN LABS: Elementary students (grades 3 to 5) participate in stations where each Lab is staffed by at least two professionals: a College level fully bilingual Latin American Professional and a stakeholder representing either a research organization or other relevant environmental organization. Our current Green Lab themes include: Air, Soils, Water

  14. Water Pollution, Environmental Science Curriculum Guide Supplement.

    Science.gov (United States)

    McKenna, Harold J.

    This curriculum guide is a 40-day unit plan on water pollution developed, in part, from the National Science Foundation Environmental Science Institutes' Ninth Grade Environmental Science Curriculum Guide. This unit contains teacher lesson plans, suggested teacher and student modules, case studies, and activities to be developed by teachers…

  15. Making Philosophy of Science Education Practical for Science Teachers

    Science.gov (United States)

    Janssen, F. J. J. M.; van Berkel, B.

    2015-04-01

    Philosophy of science education can play a vital role in the preparation and professional development of science teachers. In order to fulfill this role a philosophy of science education should be made practical for teachers. First, multiple and inherently incomplete philosophies on the teacher and teaching on what, how and why should be integrated. In this paper we describe our philosophy of science education (ASSET approach) which is composed of bounded rationalism as a guideline for understanding teachers' practical reasoning, liberal education underlying the why of teaching, scientific perspectivism as guideline for the what and educational social constructivism as guiding choices about the how of science education. Integration of multiple philosophies into a coherent philosophy of science education is necessary but not sufficient to make it practical for teachers. Philosophies are still formulated at a too abstract level to guide teachers' practical reasoning. For this purpose, a heuristic model must be developed on an intermediate level of abstraction that will provide teachers with a bridge between these abstract ideas and their specific teaching situation. We have developed and validated such a heuristic model, the CLASS model in order to complement our ASSET approach. We illustrate how science teachers use the ASSET approach and the CLASS model to make choices about the what, the how and the why of science teaching.

  16. Environmental Studies and Environmental Science at GCE '0' and 'A' Level.

    Science.gov (United States)

    Gayford, Christopher G.

    1983-01-01

    Reports on environmental studies/science at General Certificate of Examination (GCE) ordinary ("0") and advanced ("A") levels. Questionnaires were used to survey teachers (focusing on their professional training and why they teach environmental studies/science courses) and to determine the relationship between environmental…

  17. Romanticism and Romantic Science: Their Contribution to Science Education

    Science.gov (United States)

    Hadzigeorgiou, Yannis; Schulz, Roland

    2014-01-01

    The unique contributions of romanticism and romantic science have been generally ignored or undervalued in history and philosophy of science studies and science education. Although more recent research in history of science has come to delineate the value of both topics for the development of modern science, their merit for the educational field…

  18. Science education and everyday action

    Science.gov (United States)

    McCann, Wendy Renee Sherman

    2001-07-01

    This dissertation addresses three related tasks and issues in the larger field of science education. The first is to review of the several uses of "everydayness" at play in the science education literature, and in the education and social science literatures more generally. Four broad iterations of everydayness were found in science education, and these were traced and analyzed to develop their similarities, and contradictions. It was concluded that despite tendencies in science education research to suppose a fundamental demarcation either between professional science and everyday life, or between schools and everyday life, all social affairs, including professional science and activity in schools, are continuous with everyday life, and consist fundamentally in everyday, ordinary mundane actions which are ordered and organized by the participants to those social activities and occasions. The second task for this dissertation was to conduct a naturalistic, descriptive study of undergraduate-level physics laboratory activities from the analytic perspective of ethnomethodology. The study findings are presented as closely-detailed analysis of the students' methods of following their instructions and 'fitting' their observed results to a known scientific concept or principle during the enactment of their classroom laboratory activities. Based on the descriptions of students' practical work in following instructions and 'fitting'. The characterization of school science labs as an "experiment-demonstration hybrid" is developed. The third task of this dissertation was to synthesize the literature review and field study findings in order to clarify what science educators could productively mean by "everydayness", and to suggest what understandings of science education the study of everyday action recommends. It is argued that the significance of the 'experiment-demo hybrid' characterization must be seen in terms of an alternate program for science education research, which

  19. 77 FR 43849 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2012-07-26

    ... applications. Place: Hilton Garden Inn Durham Southpoint, 7007 Fayetteville Road, Durham, NC 27713. Contact... Waste Worker Health and Safety Training; 93.143, NIEHS Superfund Hazardous Substances--Basic Research and Education; 93.894, Resources and Manpower Development in the Environmental Health Sciences; 93.113...

  20. Preparing informal science educators perspectives from science communication and education

    CERN Document Server

    2017-01-01

    This book provides a diverse look at various aspects of preparing informal science educators. Much has been published about the importance of preparing formal classroom educators, but little has been written about the importance, need, and best practices for training professionals who teach in aquariums, camps, parks, museums, etc. The reader will find that as a collective the chapters of the book are well-related and paint a clear picture that there are varying ways to approach informal educator preparation, but all are important. The volume is divided into five topics: Defining Informal Science Education, Professional Development, Designing Programs, Zone of Reflexivity: The Space Between Formal and Informal Educators, and Public Communication. The authors have written chapters for practitioners, researchers and those who are interested in assessment and evaluation, formal and informal educator preparation, gender equity, place-based education, professional development, program design, reflective practice, ...

  1. Using and Developing Measurement Instruments in Science Education: A Rasch Modeling Approach. Science & Engineering Education Sources

    Science.gov (United States)

    Liu, Xiufeng

    2010-01-01

    This book meets a demand in the science education community for a comprehensive and introductory measurement book in science education. It describes measurement instruments reported in refereed science education research journals, and introduces the Rasch modeling approach to developing measurement instruments in common science assessment domains,…

  2. Environmental Science and Research Foundation annual technical report: Calendar year 1996

    International Nuclear Information System (INIS)

    Morris, R.C.; Blew, R.D.

    1997-01-01

    This Annual Technical Report describes work conducted for the Department of Energy, Idaho Operations Office (DOE-ID), by the Environmental Science and Research Foundation (Foundation). The Foundation's mission to DOE-ID provides support in several key areas. The authors conduct an environmental monitoring and surveillance program over an area covering much of the upper Snake River Plain, and provide environmental education and support services related to Idaho National Engineering and Environmental Laboratory (INEEL) natural resource issues. Also, the Foundation, with its University Affiliates, conducts ecological and radioecological research in the Idaho National Environmental Research Park. This research benefits major DOE-ID programs including Waste Management, Environmental Restoration, Spent Nuclear Fuels, and Land Management Issues. The major accomplishments of the Foundation and its University Affiliates during the calendar year 1996 are discussed

  3. Environmental Science and Research Foundation annual technical report: Calendar year 1996

    Energy Technology Data Exchange (ETDEWEB)

    Morris, R.C.; Blew, R.D. [eds.

    1997-07-01

    This Annual Technical Report describes work conducted for the Department of Energy, Idaho Operations Office (DOE-ID), by the Environmental Science and Research Foundation (Foundation). The Foundation`s mission to DOE-ID provides support in several key areas. The authors conduct an environmental monitoring and surveillance program over an area covering much of the upper Snake River Plain, and provide environmental education and support services related to Idaho National Engineering and Environmental Laboratory (INEEL) natural resource issues. Also, the Foundation, with its University Affiliates, conducts ecological and radioecological research in the Idaho National Environmental Research Park. This research benefits major DOE-ID programs including Waste Management, Environmental Restoration, Spent Nuclear Fuels, and Land Management Issues. The major accomplishments of the Foundation and its University Affiliates during the calendar year 1996 are discussed.

  4. Environmental Education: The African Dimension.

    Science.gov (United States)

    W'O Okot-Uma, Rogers; Wereko-Brobby, Charles

    1985-01-01

    Presents a historical perspective of educational and environmental curricula orientation in Africa. Examines environmentally-related problem areas (such as deforestation, pesticides, and endangered species) and lists the benefits and advantages of environmental education. A restructuring of Africa's formal education curriculum is recommended. (ML)

  5. Secondary School Students' Interests, Attitudes and Values Concerning School Science Related to Environmental Issues in Finland

    Science.gov (United States)

    Uitto, Anna; Juuti, Kalle; Lavonen, Jari; Byman, Reijo; Meisalo, Veijo

    2011-01-01

    This paper explores the relationship between students' interests in environmental issues, attitudes to environmental responsibility and biocentric values in school science education. The factors were investigated within the framework of three moderators: gender, school and residential area of the school. The survey was carried out using the…

  6. Pacific Northwest Laboratory annual report for 1993 to the DOE Office of Energy Research. Part 2: Environmental sciences

    Energy Technology Data Exchange (ETDEWEB)

    1994-04-01

    This 1993 Annual Report from Pacific Northwest Laboratory (PNL) to the US DOE describes research in environment and health conducted during fiscal year (FY) 1993. The report is divided into four parts, each in a separate volume. This part, Volume 2, covers Environmental Sciences. The research is directed toward developing a fundamental understanding of subsurface and terrestrial systems as a basis for both managing these critical resources and addressing environmental problems such as environmental restoration and global change. There are sections on Subsurface Science, Terrestrial Science, Technology Transfer, Interactions with Educational Institutions, and Laboratory Directed Research and Development.

  7. Definition: Conservation Education, Environmental Education, Outdoor Education.

    Science.gov (United States)

    1970

    Conservation education, outdoor education, and environmental education all have as a common goal the understanding and appreciation of the natural world. Outdoor education is a method of teaching wherein established disciplines, topics, and concepts which can best be taught outdoors are taught outdoors. Conservation education is the study of man's…

  8. Exploring the Effects of Communication Framed by Environmental Concern in Informal Science Education Contexts

    Science.gov (United States)

    Yocco, Victor S.

    Informal science education (ISE) venues such as zoos, nature centers, parks, and natural history museums play a critical role in allowing the general public to learn scientific concepts (National Research Council, 2009; 2010). Most adult learning of scientific concepts takes place outside of classrooms and away from work (Rennie and Williams, 2006). It is also true that zoos and natural history museums have stated missions regarding conveying concepts related to the conservation of our natural resources (Krishtalka and Humphrey, 2000; Patrick, Mathews, Ayers, and Tunicliffe, 2007). Theoretically, the successful communication of the desired message of these ISE institutions would inspire a more informed citizenry on the use and conservation of our natural resources. Framing communication is to present a topic in a manner that promote a specific view of the information. Effectively framing information can be an avenue to achieving the goal of ISE institutions (Chong & Druckman, 2007; Nisbet, 2009). Shultz and Zelezny (2003) posit that messages framed by egoistic concerns, concerns which focus on the individual, will be better received by the general public, leading to a greater likelihood for them to become engaged. This dissertation reports on a series of descriptive mixed methods studies conducted at a zoo, a natural history museum, and a science center, exploring the framing effects of communications framed by environmental concern (Schultz, 2001). In two of the studies the researcher examined the relationship between individuals' perceptions of the overlap between their lives and nature, their levels of environmental concern, and their preferences for statements designed to align with the types of environmental concern (i.e. egoistic, social-altruistic, and biospheric). Two studies were conducted using a quasi-experimental design in which the researcher randomly assigned messages framed by environmental concern while also taking measurements of prior involvement

  9. Science-Technology-Society (STS): A New Paradigm in Science Education

    Science.gov (United States)

    Mansour, Nasser

    2009-01-01

    Changes in the past two decades of goals for science education in schools have induced new orientations in science education worldwide. One of the emerging complementary approaches was the science-technology-society (STS) movement. STS has been called the current megatrend in science education. Others have called it a paradigm shift for the field…

  10. The Role of Outdoor Art in Urban Environmental Education

    Science.gov (United States)

    Filippelli, G. M.; Kesling, M.; Ryan, T.; Fraser, J.; McDonald, F.; Rollings, A.; Miss, M.; Kanpetch, B.; Trueblood, M.

    2015-12-01

    Finding ways to engage youth in inadvertent learning about nature and the environment is challenging, particularly in urban areas where environmental literacy is profoundly limited by access to safe and representative spaces. Termed the Nature Deficit Disorder, the lack of contact and connection between people and their environment leads to a less than holistic approach to environmental management at the personal and governmental levels. One of the challenges is developing ways to engage youth in science learning not by bringing them indoors to a science museum but rather by taking the science museum outdoors. Funded by the NSF Informal Science Learning program, we launched a collaborative between scientists and artists to understand the nature and impact of environmental learning through outdoor art and science programming, called StreamLines. Launched in 2014 and now near full deployment, the program is part of a bigger initiative in Indianapolis (Reconnecting to Our Waterways) to embrace the multiple waterways that traverse the city as a valuable community and health resource. This collaborative is designed to function on multiple levels. An Artist and Scientists Roundtable engages practitioners in regular conversations supplemented by external readings to share how practitioners use concepts and tools from the "opposite" side to inform their work and scholarship. Physical installations of iconic art at individual sites reflect the environmental conditions at individual sites are designed as tools for explicit and implicit learning and exploration about the environment. Music, poetry, and dance programming developed for individual sites portray cogent characteristics of place and are meant to allow visitors to see how artists engage with and draw from the environment for inspiration. A research approach unpins all of these efforts, utilizing a set of different sample populations to explore environmental education and potential advocacy after interactions with

  11. Crowdfunding for Elementary Science Educators

    Science.gov (United States)

    Reese, Jessica; Miller, Kurtz

    2017-01-01

    The inadequate funding of science education in many school districts, particularly in underserved areas, is preventing elementary science educators from realizing the full potential of the "Next Generation Science Standards" ("NGSS"). Yet many elementary science teachers may be unaware that millions of dollars per year are…

  12. Environmental Science and Research Foundation. Annual technical report, April 11, 1994--December 31, 1994

    International Nuclear Information System (INIS)

    Reynolds, T.D.; Morris, R.C.; Markham, O.D.

    1995-06-01

    This Annual Technical Report describes work conducted for the Department of Energy, Idaho Operations Office, by the Environmental Science and Research Foundation (Foundation) for work under contract DE-AC07-94ID13268. The Foundation began, on April 11, 1994, to conduct environmental surveillance near to and distant from the Idaho National Engineering Laboratory, provide environmental public relations and education related to INEL natural resource issues, and conduct ecological and radioecological research benefiting major DOE-ID programs including Waste Management, Environmental Restoration, Spent Nuclear Fuels, and Infrastructure

  13. Environmental Science and Research Foundation. Annual technical report, April 11, 1994--December 31, 1994

    Energy Technology Data Exchange (ETDEWEB)

    Reynolds, T.D.; Morris, R.C.; Markham, O.D. [eds.

    1995-06-01

    This Annual Technical Report describes work conducted for the Department of Energy, Idaho Operations Office, by the Environmental Science and Research Foundation (Foundation) for work under contract DE-AC07-94ID13268. The Foundation began, on April 11, 1994, to conduct environmental surveillance near to and distant from the Idaho National Engineering Laboratory, provide environmental public relations and education related to INEL natural resource issues, and conduct ecological and radioecological research benefiting major DOE-ID programs including Waste Management, Environmental Restoration, Spent Nuclear Fuels, and Infrastructure.

  14. Community Environmental Education as a Model for Effective Environmental Programmes

    Science.gov (United States)

    Blair, Morag

    2008-01-01

    The benefits of community environmental education outlined in environmental education literature are supported by the findings and implications of a research study undertaken in New Zealand. Evidence from a two-case case study suggests that environmental programmes guided by the key principles and practices of community environmental education,…

  15. Measuring the impact of informal science education in zoos on environmental knowledge, attitudes and behaviors

    Science.gov (United States)

    Wilson, Christopher David

    Despite the emphasis in modern zoos and aquaria on conservation and environmental education, we know very little about what people learn in these settings, and even less about how they learn it. Research on informal learning in settings such as zoos has suffered from a lack of theory, with few connections being made to theories of learning in formal settings, or to theories regarding the nature of the educational goals. This dissertation consists of three parts: the development and analysis of a test instrument designed to measure constructs of environmental learning in zoos; the application of the test instrument along with qualitative data collection in an evaluation designed to measure the effectiveness of a zoo's education programs; and the analysis of individually matched pre- and post-test data to examine how environmental learning takes place, with respect to the constructivist view of learning, as well as theories of environmental learning and the barriers to pro-environmental behavior. The test instrument consisted of 40 items split into four scales: environmental knowledge, attitudes toward the environment, support for conservation, and environmentally responsible behavior. A model-driven approach was used to develop the instrument, which was analyzed using Item Response Theory and the Rasch dichotomous measurement model. After removal of two items with extremely high difficulty, the instrument was found to be unidimensional and sufficiently reliable. The results of the IRT analyses are interpreted with respect to a modern validity framework. The evaluation portion of this study applied this test instrument to measuring the impact of zoo education programs on 750 fourth through seventh grade students. Qualitative data was collected from program observations and teacher surveys, and a comparison was also made between programs that took place at the zoo, and those that took place in the school classroom, thereby asking questions regarding the role of

  16. Environmental Influences on Adult Motivation for Career Choice in Science Professions

    Science.gov (United States)

    Fawcett-Adams, Victoria Joan

    Science, technology, engineering and math (STEM) education is an issue of great concern for the country with implications for sustaining a skilled workforce in science-based professions. This empirical study explored adults' science career choice and explored the environmental influences that motivated, influenced and shaped these choices. This qualitative study used the analytical lens of narrative inquiry storytelling and thick description. Participants lived in medium-sized rural towns and a small city, and they were adults who had been in science careers for a minimum of ten years in the fields of health care, education and agriculture. Interviews were semi-structured with open-ended questions and were recorded and transcribed verbatim. Observations took place at the workplace site. The interview transcripts were reviewed with each participant in person for authenticity and additional specific questions were designed to further explore their responses, meaning and provide accurate interpretations of the data. Themes and subthemes emerged from coding the data and suggested four dominant themes: people, identity, beliefs and attitudes, and feelings. Findings showed that people such as parents, grandparents, siblings and teachers were most influential in forming identity as well as shaping beliefs and attitudes, and feelings in science career choice. Participants did not remember educational experiences as influential; however, they did remember some teachers and advisors as influential, especially during college. The researcher recommends that parents and other adults build relationships with students specifically to discuss career opportunities. Parents and teachers should increase their knowledge and awareness of science careers. This knowledge can then contribute to a more informed conversation when discussing career objectives with students. Industry should partner with K-16 education to help develop a scientific workforce and participate in further career

  17. Exploring social networks of municipal science education stakeholders in Danish Science Municipalities

    DEFF Research Database (Denmark)

    von der Fehr, Ane

    development in the science and technology industry. Therefore, much effort has been invested to improve science education. The importance of school external stakeholders in development of education has been an increasingly emphasised, also in the field of science education. This has led to a growing focus......Science education development is a field of many interests and a key interest is recruitment of students who wish to pursue an education in science. This is an urgent societal demand in Denmark as well as internationally, since highly skilled science graduates are needed for the continuous...... involved in science education development. These municipal science education networks (MSE networks) were identified as important for development of science education in the SM project. Therefore, it was a key interest to explore these networks in order to investigate how the central stakeholders affected...

  18. Environmental Science and Research Foundation, Inc. annual technical report: Calendar year 1997

    Energy Technology Data Exchange (ETDEWEB)

    Reynolds, R.D.; Warren, R.W. [eds.

    1998-05-01

    This Annual Technical Report describes work conducted for the Department of Energy, Idaho Operations Office (DOE-ID), by the Environmental Science and Research Foundation (Foundation). The Foundation`s mission to DOE-ID provides support in several key areas. The Foundation conducts an environmental monitoring and surveillance program over an area covering much of the upper Snake River Plain, and provides environmental education and support services related to Idaho National Engineering and Environmental Laboratory (INEEL) natural resource issues. Also, the Foundation, with its University Affiliates, conducts ecological and radioecological research on the Idaho National Environmental Research Park. This research benefits major DOE-ID programs including Waste Management, Environmental Restoration, Spent Nuclear Fuels, and Land Management Issues. Summaries are included of the individual research projects.

  19. Environmental Science and Research Foundation, Inc. annual technical report: Calendar year 1997

    International Nuclear Information System (INIS)

    Reynolds, R.D.; Warren, R.W.

    1998-05-01

    This Annual Technical Report describes work conducted for the Department of Energy, Idaho Operations Office (DOE-ID), by the Environmental Science and Research Foundation (Foundation). The Foundation's mission to DOE-ID provides support in several key areas. The Foundation conducts an environmental monitoring and surveillance program over an area covering much of the upper Snake River Plain, and provides environmental education and support services related to Idaho National Engineering and Environmental Laboratory (INEEL) natural resource issues. Also, the Foundation, with its University Affiliates, conducts ecological and radioecological research on the Idaho National Environmental Research Park. This research benefits major DOE-ID programs including Waste Management, Environmental Restoration, Spent Nuclear Fuels, and Land Management Issues. Summaries are included of the individual research projects

  20. Environmental science and technology

    Energy Technology Data Exchange (ETDEWEB)

    Manahan, S.E. [Univ. of Missouri, Columbia, MO (United States)

    1998-12-31

    This complete survey of modern environmental science covers the four traditional spheres of the environment: water, air, earth, and life, and introduces a fifth sphere -- the anthrosphere -- which the author defines as the sphere of human activities, especially technology, that affect the earth. The book discusses how technology can be used in a manner that minimizes environmental disruption.

  1. Perceived barriers to online education by radiologic science educators.

    Science.gov (United States)

    Kowalczyk, Nina K

    2014-01-01

    Radiologic science programs continue to adopt the use of blended online education in their curricula, with an increase in the use of online courses since 2009. However, perceived barriers to the use of online education formats persist in the radiologic science education community. An electronic survey was conducted to explore the current status of online education in the radiologic sciences and to identify barriers to providing online courses. A random sample of 373 educators from radiography, radiation therapy, and nuclear medicine technology educational programs accredited by the Joint Review Committee on Education in Radiologic Technology and Joint Review Committee on Educational Programs in Nuclear Medicine Technology was chosen to participate in this study. A qualitative analysis of self-identified barriers to online teaching was conducted. Three common themes emerged: information technology (IT) training and support barriers, student-related barriers, and institutional barriers. Online education is not prevalent in the radiologic sciences, in part because of the need for the clinical application of radiologic science course content, but online course activity has increased substantially in radiologic science education, and blended or hybrid course designs can effectively provide opportunities for student-centered learning. Further development is needed to increase faculty IT self-efficacy and to educate faculty regarding pedagogical methods appropriate for online course delivery. To create an excellent online learning environment, educators must move beyond technology issues and focus on providing quality educational experiences for students.

  2. Improving Science and IT Literacy by Providing Urban-Based Environmental Science Research Opportunities

    Science.gov (United States)

    Cuff, K. E.; Corazza, L.; Liang, J.

    2007-12-01

    A U.C. Berkeley-based outreach program known as Environmental Science Information Technology Activities has been in operation over the past four years. The primary aim of the program is to provide opportunities for grades 9 and 10 students in diverse East San Francisco Bay Area communities to develop deeper understandings of the nature and conduct of science, which will increase their capacity to enroll and perform successfully in science, technology, engineering, and mathematics (STEM) courses in the future. Design of the program has been informed by recent research that indicates a close relationship between educational activities that promote the perception of STEM as being relevant and the ability to foster development of deeper conceptual understandings among teens. Accordingly, ESITA includes an important student-led environmental science research project component, which provides participants with opportunities to engage in research investigations that are directly linked to relevant, real-world environmental problems and issues facing their communities. Analysis of evidence gleaned from questionnaires, interviews with participants and specific assessment/evaluation instruments indicates that ESITA program activities, including after-school meetings, summer and school year research projects, and conference preparations and presentations has provided students with high-quality inquiry science experiences that increased their knowledge of STEM and IT concepts, as well as their understanding of the nature of the scientific enterprise. In addition, the program has achieved a high degree of success in that it has: enhanced participants' intellectual self-confidence with regard to STEM; developed deeper appreciation of how scientific research can contribute to the maintenance of healthy local environments; developed a greater interest in participating in STEM-related courses of study and after school programs; and improved attitudes toward STEM. Overall

  3. Scientists Interacting With University Science Educators

    Science.gov (United States)

    Spector, B. S.

    2004-12-01

    Scientists with limited time to devote to educating the public about their work will get the greatest multiplier effect for their investment of time by successfully interacting with university science educators. These university professors are the smallest and least publicized group of professionals in the chain of people working to create science literate citizens. They connect to all aspects of formal and informal education, influencing everything from what and how youngsters and adults learn science to legislative rulings. They commonly teach methods of teaching science to undergraduates aspiring to teach in K-12 settings and experienced teachers. They serve as agents for change to improve science education inside schools and at the state level K-16, including what science content courses are acceptable for teacher licensure. University science educators are most often housed in a College of Education or Department of Education. Significant differences in culture exist in the world in which marine scientists function and that in which university science educators function, even when they are in the same university. Subsequently, communication and building relationships between the groups is often difficult. Barriers stem from not understanding each other's roles and responsibilities; and different reward systems, assumptions about teaching and learning, use of language, approaches to research, etc. This presentation will provide suggestions to mitigate the barriers and enable scientists to leverage the multiplier effect saving much time and energy while ensuring the authenticity of their message is maintained. Likelihood that a scientist's message will retain its authenticity stems from criteria for a university science education position. These professors have undergraduate degrees in a natural science (e.g., biology, chemistry, physics, geology), and usually a master's degree in one of the sciences, a combination of natural sciences, or a master's including

  4. Assessment in Science Education

    Science.gov (United States)

    Rustaman, N. Y.

    2017-09-01

    An analyses study focusing on scientific reasoning literacy was conducted to strengthen the stressing on assessment in science by combining the important of the nature of science and assessment as references, higher order thinking and scientific skills in assessing science learning as well. Having background in developing science process skills test items, inquiry in its many form, scientific and STEM literacy, it is believed that inquiry based learning should first be implemented among science educators and science learners before STEM education can successfully be developed among science teachers, prospective teachers, and students at all levels. After studying thoroughly a number of science researchers through their works, a model of scientific reasoning was proposed, and also simple rubrics and some examples of the test items were introduced in this article. As it is only the beginning, further studies will still be needed in the future with the involvement of prospective science teachers who have interests in assessment, either on authentic assessment or in test items development. In balance usage of alternative assessment rubrics, as well as valid and reliable test items (standard) will be needed in accelerating STEM education in Indonesia.

  5. Inquiry-Based Integrated Science Education: Implementation of Local Content “Soil Washing” Project To Improve Junior High School Students’ Environmental Literacy

    Science.gov (United States)

    Syifahayu

    2017-02-01

    The study was conducted based on teaching and learning problems led by conventional method that had been done in the process of learning science. It gave students lack opportunities to develop their competence and thinking skills. Consequently, the process of learning science was neglected. Students did not have opportunity to improve their critical attitude and creative thinking skills. To cope this problem, the study was conducted using Project-Based Learning model through inquiry-based science education about environment. The study also used an approach called Sains Lingkungan and Teknologi masyarakat - “Saling Temas” (Environmental science and Technology in Society) which promoted the local content in Lampung as a theme in integrated science teaching and learning. The study was a quasi-experimental with pretest-posttest control group design. Initially, the subjects were given a pre-test. The experimental group was given inquiry learning method while the control group was given conventional learning. After the learning process, the subjects of both groups were given post-test. Quantitative analysis was performed using the Mann-Whitney U-test and also a qualitative descriptive. Based on the result, environmental literacy skills of students who get inquiry learning strategy, with project-based learning model on the theme soil washing, showed significant differences. The experimental group is better than the control group. Data analysis showed the p-value or sig. (2-tailed) is 0.000 <α = 0.05 with the average N-gain of experimental group is 34.72 and control group is 16.40. Besides, the learning process becomes more meaningful.

  6. Introducing Hands-on, Experiential Learning Experiences in an Urban Environmental Science Program at a Minority Serving Institution

    Science.gov (United States)

    Duzgoren-Aydin, N. S.; Freile, D.

    2013-12-01

    STEM education at New Jersey City University increasingly focuses on experiential, student-centered learning. The Department of Geoscience/Geography plays a significant role in developing and implementing a new Urban Environmental Science Program. The program aims at graduating highly skilled, demographically diverse students (14 % African-American and 18% Hispanic) to be employed in high-growth Earth and Environmental Science career paths, both at a technical (e.g. B.S.) as well as an educational (K-12 grade) (e.g. B.A) level. The core program, including the Earth and Environmental Science curricula is guided by partners (e.g. USDA-NRCS). The program is highly interdisciplinary and 'hands-on', focusing upon the high-tech practical skills and knowledge demanded of science professionals in the 21st century. The focus of the curriculum is on improving environmental quality in northern NJ, centering upon our urban community in Jersey City and Hudson County. Our Department is moving towards a more earth system science approach to learning. Most of our courses (e.g., Earth Surface Processes, Sedimentology/Stratigraphy, Earth Materials, Essential Methods, Historical Geology) have hands-on laboratory and/or field components. Although some of our other courses do not have formal laboratory components, research modules of many such courses (Geochemistry, Urban Environmental Issues and Policy and Environmental Geology) involve strong field or laboratory studies. The department has a wide range of analytical and laboratory capacities including a portable XRF, bench-top XRD and ICP-MS. In spring 2013, Dr. Duzgoren-Aydin was awarded $277K in Higher Education Equipment Leasing Fund monies from the University in order to establish an Environmental Teaching and Research Laboratory. The addition of these funds will make it possible for the department to increase its instrumentation capacity by adding a mercury analyzer, Ion Chromatography and C-N-S analyzer, as well as updating

  7. 75 FR 65365 - National Institute of Environmental Health Sciences;

    Science.gov (United States)

    2010-10-22

    ... Environmental Health Sciences; Notice of Closed Meetings Pursuant to section 10(d) of the Federal Advisory... clearly unwarranted invasion of personal privacy. Name of Committee: Environmental Health Sciences Review... evaluate grant applications. Place: Nat. Inst. of Environmental Health Sciences, Building 101, Rodbell...

  8. Ethiopian Journal of Education and Sciences

    African Journals Online (AJOL)

    The Ethiopian Journal of Education and Sciences focuses on publishing articles relating to education and sciences. It publishes ... The objective is to create forum for researchers in education and sciences. ... AJOL African Journals Online.

  9. Improving Health with Science: Exploring Community-Driven Science Education in Kenya

    Science.gov (United States)

    Leak, Anne Emerson

    This study examines the role of place-based science education in fostering student-driven health interventions. While literature shows the need to connect science with students' place and community, there is limited understanding of strategies for doing so. Making such connections is important for underrepresented students who tend to perceive learning science in school as disconnected to their experiences out of school (Aikenhead, Calabrese-Barton, & Chinn, 2006). To better understand how students can learn to connect place and community with science and engineering practices in a village in Kenya, I worked with community leaders, teachers, and students to develop and study an education program (a school-based health club) with the goal of improving knowledge of health and sanitation in a Kenyan village. While students selected the health topics and problems they hoped to address through participating in the club, the topics were taught with a focus on providing opportunities for students to learn the practices of science and health applications of these practices. Students learned chemistry, physics, environmental science, and engineering to help them address the health problems they had identified in their community. Surveys, student artifacts, ethnographic field notes, and interview data from six months of field research were used to examine the following questions: (1) In what ways were learning opportunities planned for using science and engineering practices to improve community health? (2) In what ways did students apply science and engineering practices and knowledge learned from the health club in their school, homes, and community? and (3) What factors seemed to influence whether students applied or intended to apply what they learned in the health club? Drawing on place-based science education theory and community-engagement models of health, process and structural coding (Saldana, 2013) were used to determine patterns in students' applications of their

  10. Augmented Reality for Science Education

    DEFF Research Database (Denmark)

    Brandt, Harald; Nielsen, Birgitte Lund; Georgsen, Marianne

    Augmented reality (AR) holds great promise as a learning tool. So far, however, most research has looked at the technology itself – and AR has been used primarily for commercial purposes. As a learning tool, AR supports an inquiry-based approach to science education with a high level of student...... involvement. The AR-sci-project (Augmented Reality for SCIence education) addresses the issue of applying augmented reality in developing innovative science education and enhancing the quality of science teaching and learning....

  11. Assessing Earth and Environmental Science Enrollment Trends in Texas Public High Schools

    Science.gov (United States)

    Sanders, Joan G.

    2012-01-01

    Scope and Method of Study: This study assesses the status of Earth and environmental sciences education in Texas Public High Schools by analyzing enrollment proportions of 11th and 12th grade students in 607 Independent School Districts (ISD) for the 2010-2011 academic school year using a quantitative, non-experimental alpha research design. This…

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

    Science.gov (United States)

    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

  13. Environmental Science and Technology

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2011-07-01

    The Program on Environmental Science and Technology comprehends environmental chemistry (water, soil and atmospheric chemistry), clean technologies (desulfurization of diesel and oil, biodegradable polymers and structural modification of polymers, recycling, pyrolysis of dangerous chemicals by molten salt technology), nanotechnology (magnetic nanoparticles, dendrimers, nano biomarkers, catalyzers) and chemical characterization of nuclear fuel and nuclear fuel cycle waste (chemical and isotopic characterization)

  14. Report on the 4th Conference on Environmental Science of the Carpathian Basin

    International Nuclear Information System (INIS)

    Kiss, A.Z.

    2008-01-01

    Complete text of publication follows. The main organizers of the conference were the Faculty of Science and Technology of the University of Debrecen and the Sapientia - Hungarian University of Transylvania, Faculty of Science and Art, Cluj-Napoca, Romania (the proposer of this series of conferences). The Institute of Nuclear Research of the Hungarian Academy of Sciences (ATOMKI) took part in the organization as its Hertelendi Ede Environmental Research Laboratory and the Ion Beam Application Laboratory are engaged in the study of the environment of the Carpathian Basin. Moreover the Department of Environmental Physics, run jointly by the University of Debrecen and ATOMKI, plays an important role in teaching environmental physics at the university. The conference was held on 28-29 March, 2008, in the building of the Regional Committee of the Hungarian Academy of Sciences (HAS) in Debrecen. The aim of the conference was to bring together scientists and students from different countries, involved in various aspects of environmental science and technology, since the common environmental problems of the Carpathian Basin to be solved make necessary the cooperation between them, living and working in different parts of the basin. The conference gave an opportunity to show the latest results in these fields, and in the same time it was an occasion for the young scientists to be introduced and to exchange experience. The scientific sections were the followings: environmental science and education, environmental chemistry, environmental physics, environmental geography, environmental protection and environmental technology, environmental biology and nature protection, landscape ecology and urban ecology. The number of registered participants (161) was the largest since the beginning (2005) of the conference series. They arrived from five countries (Hungary, Rumania, Slovakia, Croatia and Serbia), several institutions from 27 towns of the Carpathian Basin. The number of oral

  15. Graduate Experience in Science Education: the development of a science education course for biomedical science graduate students.

    Science.gov (United States)

    Markowitz, Dina G; DuPré, Michael J

    2007-01-01

    The University of Rochester's Graduate Experience in Science Education (GESE) course familiarizes biomedical science graduate students interested in pursuing academic career tracks with a fundamental understanding of some of the theory, principles, and concepts of science education. This one-semester elective course provides graduate students with practical teaching and communication skills to help them better relate science content to, and increase their confidence in, their own teaching abilities. The 2-h weekly sessions include an introduction to cognitive hierarchies, learning styles, and multiple intelligences; modeling and coaching some practical aspects of science education pedagogy; lesson-planning skills; an introduction to instructional methods such as case studies and problem-based learning; and use of computer-based instructional technologies. It is hoped that the early development of knowledge and skills about teaching and learning will encourage graduate students to continue their growth as educators throughout their careers. This article summarizes the GESE course and presents evidence on the effectiveness of this course in providing graduate students with information about teaching and learning that they will use throughout their careers.

  16. Children, teachers and nature: An analysis of an environmental education program

    Science.gov (United States)

    Cheng, Judith Chen-Hsuan

    Environmental education is an important tool for providing knowledge, supporting positive attitudes toward nature, and building skills to protect and improve the environment. Because of limited funding sources and increasing environmental challenges, it is important to provide effective environmental education programs. Program evaluation is one strategy to engage stakeholders and increase program effectiveness. An evaluation of a fourth grade environmental education program, Lagoon Quest developed by Brevard Zoo, provides an unique opportunity to answer several questions about implementing an effective environmental education program. The first question is about the effectiveness of Lagoon Quest. Evaluation data are reported in a case study that provides details about the development of the evaluation questions and evaluation instruments. The pre/posttest comparison suggests that participating in Lagoon Quest effectively increases students' knowledge of Indian River Lagoon (mean increase = 5.03, pteachers and parents indicate that the program positively influenced the students and are supportive of it. Lagoon Quest is now a required program in the fourth grade curriculum in Brevard County, which raises the second question: how do teachers react to a required fourth grade program? Teachers' prior experience in environmental education, science education, Lagoon Quest and their attitudes toward Lagoon Quest were examined. A teacher survey was conducted to explore teachers' attitudes, but the low response rate necessitated a process to explore non-respondents' attitudes. Follow-up focus groups at schools with few respondents suggest that teachers who had prior experience in teaching science were more likely to be highly supportive of Lagoon Quest and were more likely to use additional resources to support the program. Also, teachers' interest in Indian River Lagoon is positively associated with their attitude toward nature. The third question uses Lagoon Quest to

  17. Science education for empowerment and social change: a case study of a teacher educator in urban Pakistan

    Science.gov (United States)

    Zahur, Rubina; Calabrese Barton, Angela; Upadhyay, Bhaskar Raj

    2002-09-01

    In this manuscript we focus on the question, 'What should be the purpose of science education for children of the very poor class in caste-oriented developing countries such as Pakistan?' In other words, in a country where the literacy rate hovers around 10 per cent for the poorest segment of society and where there is no expectation that children will complete primary school, of what importance is primary science education and to what end should it be offered in schools? We begin a conversation around this question by presenting, in this manuscript, a case study of one teacher educator whose beliefs and practices sharply deviate from the norm - she believes science education ought to be about empowering students to make physical and political changes in their community. In particular, using the rich, contextual interview and observational data generated through case study, we show how Haleema's (pseudonym) orientation to science teacher education are buttressed by three fundamental beliefs: that low levels of literacy and school achievement among poor children have as much to do with poor families' lack of power/influence on the purposes and processes of schooling as it has to do with opportunities and resources; that school science can begin to address inequalities in power by fostering a kind of scientific literacy among children that leads to individual and community empowerment around health and environmental issues, the very science-related issues that divide quality of life and opportunity for poor families; and that teacher education programmes can play a role in transforming a society's views about how science and scientific practices might play a role in bringing communities together to effect change for the better.

  18. An investigation of the artifacts, outcomes, and processes of constructing computer games about environmental science in a fifth grade science classroom

    Science.gov (United States)

    Baytak, Ahmet

    Among educational researchers and practitioners, there is a growing interest in employing computer games for pedagogical purposes. The present research integrated a technology education class and a science class where 5 th graders learned about environmental issues by designing games that involved environmental concepts. The purposes of this study were to investigate how designing computer games affected the development of students' environmental knowledge, programming knowledge, environmental awareness and interest in computers. It also explored the nature of the artifacts developed and the types of knowledge represented therein. A case study (Yin, 2003) was employed within the context of a 5 th grade elementary science classroom. Fifth graders designed computer games about environmental issues to present to 2nd graders by using Scratch software. The analysis of this study was based on multiple data sources: students' pre- and post-test scores on environmental awareness, their environmental knowledge, their interest in computer science, and their game design. Included in the analyses were also data from students' computer games, participant observations, and structured interviews. The results of the study showed that students were able to successfully design functional games that represented their understanding of environment, even though the gain between pre- and post-environmental knowledge test and environmental awareness survey were minimal. The findings indicate that all students were able to use various game characteristics and programming concepts, but their prior experience with the design software affected their representations. The analyses of the interview transcriptions and games show that students improved their programming skills and that they wanted to do similar projects for other subject areas in the future. Observations showed that game design appeared to lead to knowledge-building, interaction and collaboration among students. This, in turn

  19. Soil science and geology: Connects, disconnects and new opportunities in geoscience education

    Science.gov (United States)

    Landa, E.R.

    2004-01-01

    Despite historical linkages, the fields of geology and soil science have developed along largely divergent paths in the United States during much of the mid- to late- twentieth century. The shift in recent decades within both disciplines to greater emphasis on environmental quality issues and a systems approach has created new opportunities for collaboration and cross-training. Because of the importance of the soil as a dynamic interface between the hydrosphere, biosphere, atmosphere, and lithosphere, introductory and advanced soil science classes are now being taught in a number of earth and environmental science departments. The National Research Council's recent report, Basic Research Opportunities in Earth Science, highlights the soil zone as part of the land surface-to-groundwater "critical zone" requiring additional investigation. To better prepare geology undergraduates to deal with complex environmental problems, their training should include a fundamental understanding of the nature and properties of soils. Those undergraduate geology students with an interest in this area should be encouraged to view soil science as a viable earth science specialty area for graduate study. Summer internships such as those offered by the National Science Foundation-funded Integrative Graduate Education, Research, and Training (IGERT) programs offer geology undergraduates the opportunity to explore research and career opportunities in soil science.

  20. Science and Society - Problems, issues and dilemmas in science education

    CERN Multimedia

    2001-01-01

    Next in CERN's series of Science and Society speakers is Jonathan Osborne, Senior Lecturer in Science Education at King's College London. On Thursday 26 April, Dr Osborne will speak in the CERN main auditorium about current issues in science education in the light of an ever more science-based society. Jonathan Osborne, Senior Lecturer in Science Education at King's College London. Does science deserve a place at the curriculum high table of each student or is it just a gateway to a set of limited career options in science and technology? This question leads us to an important change in our ideas of what science education has been so far and what it must be. Basic knowledge of science and technology has traditionally been considered as just a starting point for those who wanted to build up a career in scientific research. But nowadays, the processes of science, the analysis of risks and benefits, and a knowledge of the social practices of science are necessary for every citizen. This new way of looking at s...

  1. Citizen science can improve conservation science, natural resource management, and environmental protection

    Science.gov (United States)

    McKinley, Duncan C.; Miller-Rushing, Abe J.; Ballard, Heidi L.; Bonney, Rick; Brown, Hutch; Cook-Patton, Susan; Evans, Daniel M.; French, Rebecca A.; Parrish, Julia; Phillips, Tina B.; Ryan, Sean F.; Shanley, Lea A.; Shirk, Jennifer L.; Stepenuck, Kristine F.; Weltzin, Jake F.; Wiggins, Andrea; Boyle, Owen D.; Briggs, Russell D.; Chapin, Stuart F.; Hewitt, David A.; Preuss, Peter W.; Soukup, Michael A.

    2017-01-01

    Citizen science has advanced science for hundreds of years, contributed to many peer-reviewed articles, and informed land management decisions and policies across the United States. Over the last 10 years, citizen science has grown immensely in the United States and many other countries. Here, we show how citizen science is a powerful tool for tackling many of the challenges faced in the field of conservation biology. We describe the two interwoven paths by which citizen science can improve conservation efforts, natural resource management, and environmental protection. The first path includes building scientific knowledge, while the other path involves informing policy and encouraging public action. We explore how citizen science is currently used and describe the investments needed to create a citizen science program. We find that:Citizen science already contributes substantially to many domains of science, including conservation, natural resource, and environmental science. Citizen science informs natural resource management, environmental protection, and policymaking and fosters public input and engagement.Many types of projects can benefit from citizen science, but one must be careful to match the needs for science and public involvement with the right type of citizen science project and the right method of public participation.Citizen science is a rigorous process of scientific discovery, indistinguishable from conventional science apart from the participation of volunteers. When properly designed, carried out, and evaluated, citizen science can provide sound science, efficiently generate high-quality data, and help solve problems.

  2. Fermilab Education Office: Science Adventures

    Science.gov (United States)

    Search The Education Office: Science Adventures Adventure Catalog Search for Adventures Calendar Class Facebook Group. Contact: Science Adventures Registrar, Education Office Fermilab, MS 777, P.O. Box 500 it again." Opportunities for Instructors The Education Office has openings for instructors who

  3. Science Education: The New Humanity?

    Science.gov (United States)

    Douglas, John H.

    1973-01-01

    Summarizes science education trends, problems, and controversies at the elementary, secondary, and higher education levels beginning with the Physical Science Study Committee course, and discusses the present status concerning the application of the Fourth Revolution to the education system. (CC)

  4. Science Education: Issues, Approaches and Challenges

    Directory of Open Access Journals (Sweden)

    Shairose Irfan Jessani

    2015-06-01

    Full Text Available In today’s global education system, science education is much more than fact-based knowledge. Science education becomes meaningless and incomprehensible for learners, if the learners are unable to relate it with their lives. It is thus recommended that Pakistan, like many other countries worldwide should adopt Science Technology Society (STS approach for delivery of science education. The purpose of the STS approach lies in developing scientifically literate citizens who can make conscious decisions about the socio-scientific issues that impact their lives. The challenges in adopting this approach for Pakistan lie in four areas that will completely need to be revamped according to STS approach. These areas include: the examination system; science textbooks; science teacher education programs; and available resources and school facilities.

  5. Remodeling Science Education

    Science.gov (United States)

    Hestenes, David

    2013-01-01

    Radical reform in science and mathematics education is needed to prepare citizens for challenges of the emerging knowledge-based global economy. We consider definite proposals to establish: (1) "Standards of science and math literacy" for all students. (2) "Integration of the science curriculum" with structure of matter,…

  6. Environmental education as part of compulsory education at school

    Science.gov (United States)

    Dimitrova, Boyanka

    2013-04-01

    Environmental education in schools is an element of civic education and skills, the students should learn in school. This is part of the state and public order in the school and as such lies in the mandatory training documentation for various objects from the natural and social sciences. With the idea to help teachers in this activity in recent years with teachers, students, and government and municipal authorities had organized a number of activities aimed at: 1. Targeted analysis of curricula for middle school and increase their knowledge and professional competence of teachers towards the standards set forth by the state educational requirements, analysis shows that knowledge is competencies aimed at environmental education of young people are out (to varying degrees) in significant part of the subjects taught in secondary schools - man and society, and man and nature (in early stages) Geography (including the risks associated with natural - causes and effects), Biology and Health Education, Chemistry and protection of the environment, physics and astronomy, history and civilization and interdisciplinary civic education field. 2. Seminar courses to acquire skills to conduct interactive activities with students and in conjunction with textbooks (Green Package, Natura 2000, WSP, Flupi for a better environment). 3. Visits interesting and protected areas and objects by exploring opportunities for outings with students. 4. Conducting workshops and classes using the provided tools, techniques and interesting games aimed at awareness of the need for care and attention to our surroundings. 5. Organizing and conducting competitions between students from schools in our city, usually associated with the most popular day - Earth Day, World Day for Environmental Protection, Day of Danube). 6. Participation in outdoor activities - studying the structure and features of parks hometown, Work shop for making objects from natural materials and waste materials; race making ikebana

  7. The DOE/NREL Environmental Science Program

    International Nuclear Information System (INIS)

    Douglas R. Lawson; Michael Gurevich

    2001-01-01

    This paper summarizes the several of the studies in the Environmental Science Program being sponsored by DOE's Office of Heavy Vehicle Technologies (OHVT) through the National Renewable Energy Laboratory (NREL). The goal of the Environmental Science Program is to understand atmospheric impacts and potential health effects that may be caused by the use of petroleum-based fuels and alternative transportation fuels from mobile sources. The Program is regulatory-driven, and focuses on ozone, airborne particles, visibility and regional haze, air toxics, and health effects of air pollutants. Each project in the Program is designed to address policy-relevant objectives. Current projects in the Environmental Science Program have four areas of focus: improving technology for emissions measurements; vehicle emissions measurements; emission inventory development/improvement; ambient impacts, including health effects

  8. The DOE/NREL Environmental Science Program

    Energy Technology Data Exchange (ETDEWEB)

    Douglas R. Lawson; Michael Gurevich

    2001-05-14

    This paper summarizes the several of the studies in the Environmental Science Program being sponsored by DOE's Office of Heavy Vehicle Technologies (OHVT) through the National Renewable Energy Laboratory (NREL). The goal of the Environmental Science Program is to understand atmospheric impacts and potential health effects that may be caused by the use of petroleum-based fuels and alternative transportation fuels from mobile sources. The Program is regulatory-driven, and focuses on ozone, airborne particles, visibility and regional haze, air toxics, and health effects of air pollutants. Each project in the Program is designed to address policy-relevant objectives. Current projects in the Environmental Science Program have four areas of focus: improving technology for emissions measurements; vehicle emissions measurements; emission inventory development/improvement; ambient impacts, including health effects.

  9. "Back to the Basics" Through Environmental Education.

    Science.gov (United States)

    Christian, Adelaide

    Environmental education is proposed as a viable means of improving the educational system. The rationale for teaching environmental education is based in part upon White's principles of education for Seventh-day Adventists and upon Noel McInnis's views of what makes education environmental. An overview of environmental education characterizes it…

  10. Uncovering Students' Environmental Identity: An Exploration of Activities in an Environmental Science Course

    Science.gov (United States)

    Blatt, Erica

    2014-01-01

    This study at a public high school in the Northeastern United States explores how students' environmental identities are affected by various activities in an Environmental Science course. Data was collected as part of an ethnographic study involving an Environmental Science teacher and her tenth-twelfth grade students. The results focus on…

  11. Synchrotron Environmental Science-I Workshop Report

    International Nuclear Information System (INIS)

    1999-01-01

    Attendees of the Synchrotrons Environmental Science 1 (SES-1) workshop represented a broad spectrum of environmental science research areas and expertise in all of the current synchrotrons techniques (X-ray scattering and diffraction, X-ray absorption spectroscopy, and two- and three-dimensional X-ray imaging). These individuals came together to discuss current measurement obstacles in environmental research and, more specifically, ways to overcome such obstacles by applying synchrotrons radiation techniques. Significant obstacles in measurement affect virtually all of the research issues described. Attendees identified synchrotrons approaches of potential value in their research. A number of the environmental research studies discussed are currently being addressed with some success by synchrotron-based approaches. Nevertheless, improvements in low-Z measurement capabilities are needed to facilitate the use of synchrotrons radiation methodologies in environmental research

  12. Synchrotron Environmental Science-I Workshop Report.

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    1999-07-08

    Attendees of the Synchrotrons Environmental Science 1 (SES-1) workshop represented a broad spectrum of environmental science research areas and expertise in all of the current synchrotrons techniques (X-ray scattering and diffraction, X-ray absorption spectroscopy, and two- and three-dimensional X-ray imaging). These individuals came together to discuss current measurement obstacles in environmental research and, more specifically, ways to overcome such obstacles by applying synchrotrons radiation techniques. Significant obstacles in measurement affect virtually all of the research issues described. Attendees identified synchrotrons approaches of potential value in their research. A number of the environmental research studies discussed are currently being addressed with some success by synchrotron-based approaches. Nevertheless, improvements in low-Z measurement capabilities are needed to facilitate the use of synchrotrons radiation methodologies in environmental research.

  13. Solar Ethics: A New Paradigm for Environmental Ethics and Education?

    Science.gov (United States)

    Peters, Michael A.; Hung, Ruyu

    2009-01-01

    This article provides grounds for a new paradigm of environmental ethics and education based on the centrality of the sun and solar system--a shift from anthropocentrism to solar systemism. The article provides some grounds for this shift from the physical sciences that considers the planet Earth as part of a wider system that is dependent upon…

  14. Multicultural Science Education and Curriculum Materials

    Science.gov (United States)

    Atwater, Mary M.

    2010-01-01

    This article describes multicultural science education and explains the purposes of multicultural science curricula. It also serves as an introductory article for the other multicultural science education activities in this special issue of "Science Activities".

  15. The precautionary principle in environmental science.

    Science.gov (United States)

    Kriebel, D; Tickner, J; Epstein, P; Lemons, J; Levins, R; Loechler, E L; Quinn, M; Rudel, R; Schettler, T; Stoto, M

    2001-01-01

    Environmental scientists play a key role in society's responses to environmental problems, and many of the studies they perform are intended ultimately to affect policy. The precautionary principle, proposed as a new guideline in environmental decision making, has four central components: taking preventive action in the face of uncertainty; shifting the burden of proof to the proponents of an activity; exploring a wide range of alternatives to possibly harmful actions; and increasing public participation in decision making. In this paper we examine the implications of the precautionary principle for environmental scientists, whose work often involves studying highly complex, poorly understood systems, while at the same time facing conflicting pressures from those who seek to balance economic growth and environmental protection. In this complicated and contested terrain, it is useful to examine the methodologies of science and to consider ways that, without compromising integrity and objectivity, research can be more or less helpful to those who would act with precaution. We argue that a shift to more precautionary policies creates opportunities and challenges for scientists to think differently about the ways they conduct studies and communicate results. There is a complicated feedback relation between the discoveries of science and the setting of policy. While maintaining their objectivity and focus on understanding the world, environmental scientists should be aware of the policy uses of their work and of their social responsibility to do science that protects human health and the environment. The precautionary principle highlights this tight, challenging linkage between science and policy. PMID:11673114

  16. Democratizing science and technology education: Perspectives from the philosophy of education

    Science.gov (United States)

    Pierce, Clayton Todd

    This study examines conceptualizations of science and technology and their relation to ideas of democratic education in the history of philosophy of education. My genealogical analysis begins by tracing the anti-democratic emergence of ideas and values of science and technology that have evolved through ancient and modern periods within the philosophy of education and continue to shape the ways science and technology are understood and treated in educational settings. From my critical engagement with Plato's Republic and Rousseau's Emile, I argue that anti-democratic structures and values have been embedded in philosophy of education through Plato's educational theory of techne and Rousseau's pedagogical theory that involves science and technology as important educational force. Following this theme, I analyze the work of John Dewey and Herbert Marcuse and their shared project for democratizing science and technology through education. Through a critical comparison of both theorists' models, I suggest that each provides positive legacies for philosophy of education to draw upon in rethinking the intersection of science, technology, and education: a strong model for understanding public problems associated with a highly technological and scientific society and a reconstructive framework for values and sensibilities that demands a new value relationship to be developed between humans and science and technology. Finally, I situate my critique and assessment of this history in the philosophy of education within the current science and technology education reform movement in the United States. I claim that the official models of science and technological literacy and inquiry, as constructed by the National Academy of Sciences and a host of governmental policies, shape science and technology education with a decidedly neo-liberal focus and purpose. In response to this anti-democratic movement I offer an alternative position that utilizes a counter-epistemology to the

  17. The politics of federal environmental education policy

    Science.gov (United States)

    Crouch, Richard Craig

    Both environmental governance1 and education governance 2 occupy contested territory in contemporary US political discourse. Environmental education (EE) policy has emerged at this intersection and taken on aspects of both controversies. Central to debates surrounding environmental education are still unresolved issues concerning the role of the federal government in education, the role of education in citizen-making, and the role of the public in environmental governance. As a case study of the politics of environmental education policy, I explore these issues as they relate to the National Environmental Education Act of 1990,3 attempts at its reauthorization, its continued appropriations, and its current state of policy stasis. The political controversy over the federal role in environmental education is an appropriate case study of environmental education politics insofar as it reflects the different positions held by actor groups with regard to the definition, efficacy, and legitimacy of environmental education. At the core of these debates, as we will see, is a definitional crisis---that is, there is no common understanding across the relevant actor groups as to what environmental education is, or should be. I suggest here that this definitional issue can be best understood as having technical, ideological, and structural components4---all of which are mutually reinforcing and thus perpetuate the stasis in federal environmental education policy. 1I rely on Durant, Fiorino and O'leary's definition of environmental governance in Environmental Governance Reconsidered ; "In the term environmental governance, we refer to the increasingly collaborative nature of [environmental and natural resource] policy formulation and implementation. In this vein, a wide array of third parties (for example, actors in the profit sector, the nonprofit sector, and civic society), in addition to government agencies, comprise non hierarchical networks of actors wielding a variety of

  18. A science data gateway for environmental management: A SCIENCE DATA GATEWAY FOR ENVIRONMENTAL MANAGEMENT

    Energy Technology Data Exchange (ETDEWEB)

    Agarwal, Deborah A. [Lawrence Berkeley National Lab. (LBNL), Berkeley, CA (United States); Faybishenko, Boris [Lawrence Berkeley National Lab. (LBNL), Berkeley, CA (United States); Freedman, Vicky L. [Pacific Northwest National Lab. (PNNL), Richland, WA (United States); Krishnan, Harinarayan [Lawrence Berkeley National Lab. (LBNL), Berkeley, CA (United States); Kushner, Gary [Lawrence Berkeley National Lab. (LBNL), Berkeley, CA (United States); Lansing, Carina [Pacific Northwest National Lab. (PNNL), Richland, WA (United States); Porter, Ellen [Pacific Northwest National Lab. (PNNL), Richland, WA (United States); Romosan, Alexandru [Lawrence Berkeley National Lab. (LBNL), Berkeley, CA (United States); Shoshani, Arie [Lawrence Berkeley National Lab. (LBNL), Berkeley, CA (United States); Wainwright, Haruko [Lawrence Berkeley National Lab. (LBNL), Berkeley, CA (United States); Weidmer, Arthur [Lawrence Berkeley National Lab. (LBNL), Berkeley, CA (United States); Wu, Kesheng [Lawrence Berkeley National Lab. (LBNL), Berkeley, CA (United States)

    2015-10-12

    Science data gateways are effective in providing complex science data collections to the world-wide user communities. In this paper we describe a gateway for the Advanced Simulation Capability for Environmental Management (ASCEM) framework. Built on top of established web service technologies, the ASCEM data gateway is specifically designed for environmental modeling applications. Its key distinguishing features include: (1) handling of complex spatiotemporal data, (2) offering a variety of selective data access mechanisms, (3) providing state of the art plotting and visualization of spatiotemporal data records, and (4) integrating seamlessly with a distributed workflow system using a RESTful interface. ASCEM project scientists have been using this data gateway since 2011.

  19. Self-efficacy in Environmental Education: Experiences of elementary education preservice teachers

    Science.gov (United States)

    Gardner, Cynthia Crompton

    Despite research showing Environmental Education can provide positive student outcomes in academic achievement, critical thinking, motivation and engagement (Ernst, 2007; Lieberman & Hoody, 1998; Orr, 1992; Palmer, 1998; Powers, 2004; Volk & Cheak, 2003), Environmental Education is currently not a critical element in American public school K-12 education. The present study investigates self-efficacy in Environmental Education through a mixed methods research approach. The data reveal the participants' perspectives of their sense of self-efficacy in Environmental Education. It adds to the body of work on Environmental Education and self-efficacy by specifically investigating the topics through interviews with preservice teachers. Purposeful sampling is used to identify preservice elementary education teachers in their senior year of college with a high measure of self-efficacy. Self-efficacy is measured using the Environmental Education Efficacy Belief Instrument (Sia, 1992). Forty-six preservice teachers completed the instrument. Six preservice teachers were interviewed to determine experiences that impact their self-efficacy in Environmental Education. Continual comparison and cross-case analysis are used to analyze the data. The results reveal a relationship between personal experiences with nature as a young child and current beliefs toward their personal efficacy and teaching outcome efficacy in Environmental Education. Similar to the findings of Sia (1992), the researcher discovered that preservice teachers realize that they lack sufficient knowledge and skill in Environmental Education but believe that effective teaching can increase students understanding of Environmental Education. While the preservice teachers do not believe they will teach Environmental Education as well as other subjects, they will continually seek out better ways to teach Environmental Education. Interviews with participants who had a high self-efficacy revealed the importance of

  20. Environmental Education Strategic Plan

    Energy Technology Data Exchange (ETDEWEB)

    None

    1991-12-01

    This document is designed to guide the Environmental Education and Development Branch (EM-522) of the EM Office of Technology (OTD) Development, Technology Integration and Environmental Education Division (EM-52) in planning and executing its program through EM staff, Operations Offices, National Laboratories, contractors, and others.

  1. Conceptual Challenges for Environmental Education: Advocacy, Autonomy, Implicit Education and Values

    Science.gov (United States)

    Schlottmann, Christopher

    2012-01-01

    "Conceptual Challenges for Environmental Education" is a critical analysis of environmental education from the perspective of educational ethics. It spells out elements of the conceptual foundations of an environmental education theory--among them implicit education, advocacy, Decade of Education for Sustainable Development, and climate…

  2. Making Philosophy of Science Education Practical for Science Teachers

    Science.gov (United States)

    Janssen, F. J. J. M.; van Berkel, B.

    2015-01-01

    Philosophy of science education can play a vital role in the preparation and professional development of science teachers. In order to fulfill this role a philosophy of science education should be made practical for teachers. First, multiple and inherently incomplete philosophies on the teacher and teaching on what, how and why should be…

  3. Educational initiatives in environmental restoration and waste management

    International Nuclear Information System (INIS)

    Prestwich, S.M.

    1990-01-01

    Policy-makers responding to the urgency of the demands for a clean environment are finding that America lacks the technical know-how and the pool of technicians, scientists, and engineers to meet the environmental challenges. In response to the need for a technically skilled work force, government agencies and the private sector have worked to assess the probable effect of shortages and have sought ways to prevent the problem. The US Department of Energy (DOE) and its predecessor agencies have historically supported strong linkages between the academic community - the providers of scientists and engineers - and the department - the users of those workers - to assure an adequate supply of appropriately educated technicians, scientists, and engineers to conduct basic and applied research in support of the DOE's mission and to implement that mission. One of the department's challenges is the minimization, management, and cleanup of waste materials generated from departmental operations. The recently published Environmental Restoration and Waste Management Five-Year Plan for fiscal years 1992 through 1996 reaffirms DOE's policy of compliance with environmental laws and regulations. It also maps out the newly created Office of Environmental Restoration and Waste Management's aggressive programs to improve training and education, to arouse interest in pursuit of science/engineering careers, and to place special emphasis on recruiting minorities and women to technical fields vital to the environmental restoration/waste management mission

  4. Science Education Notes.

    Science.gov (United States)

    School Science Review, 1982

    1982-01-01

    Discusses: (1) the nature of science; (2) Ausubel's learning theory and its application to introductory science; and (3) mathematics and physics instruction. Outlines a checklist approach to Certificate of Extended Education (CSE) practical assessment in biology. (JN)

  5. Science education ahead?

    Science.gov (United States)

    1999-01-01

    In spite of the achievements and successes of science education in recent years, certain problems undoubtedly remain. Firstly the content taught at secondary level has largely remained unchanged from what had been originally intended to meet the needs of those who would go on to become scientists. Secondly the curriculum is overloaded with factual content rather than emphasizing applications of scientific knowledge and skills and the connections between science and technology. Thirdly the curriculum does not relate to the needs and interests of the pupils. A recent report entitled Beyond 2000: Science Education for the Future, derived from a series of seminars funded by the Nuffield Foundation, attempts to address these issues by setting out clear aims and describing new approaches to achieve them. Joint editors of the report are Robin Millar of the University of York and Jonathan Osborne of King's College London. The recommendations are that the curriculum should contain a clear statement of its aims, with the 5 - 16 science curriculum seen as enhancing general `scientific literacy'. At key stage 4 there should be more differentiation between the literacy elements and those designed for the early stages of a specialist training in science; up to the end of key stage 3 a common curriculum is still appropriate. The curriculum should be presented clearly and simply, following on from the statement of aims, and should provide young people with an understanding of some key `ideas about science'. A wide variety of teaching methods and approaches should be encouraged, and the assessment approaches for reporting on students' performance should focus on their ability to understand and interpret information as well as their knowledge and understanding of scientific ideas. The last three recommendations in the report cover the incorporation of aspects of technology and the applications of science into the curriculum, with no substantial change overall in the short term but a

  6. Archives: African Journal of Environmental Science and Technology

    African Journals Online (AJOL)

    Items 1 - 50 of 117 ... Archives: African Journal of Environmental Science and Technology. Journal Home > Archives: African Journal of Environmental Science and Technology. Log in or Register to get access to full text downloads.

  7. Science Education - Deja Vu Revised.

    Science.gov (United States)

    Walsh, John

    1982-01-01

    Summarizes views expressed and issues raised at the National Convocation on Precollege Education in Mathematics and Science and another meeting to establish a coalition of affiliates for science and mathematics education. (DC)

  8. Reforming Science Education: Part II. Utilizing Kieran Egan's Educational Metatheory

    Science.gov (United States)

    Schulz, Roland M.

    2009-04-01

    This paper is the second of two parts and continues the conversation which had called for a shift in the conceptual focus of science education towards philosophy of education, with the requirement to develop a discipline-specific “philosophy” of science education. In Part I, conflicting conceptions of science literacy were identified with disparate “visions” tied to competing research programs as well as school-based curricular paradigms. The impasse in the goals of science education and thereto, the contending views of science literacy, were themselves associated with three underlying fundamental aims of education (knowledge-itself; personal development; socialization) which, it was argued, usually undercut the potential of each other. During periods of “crisis-talk” and throughout science educational history these three aims have repeatedly attempted to assert themselves. The inability of science education research to affect long-term change in classrooms was correlated not only to the failure to reach a consensus on the aims (due to competing programs and to the educational ideologies of their social groups), but especially to the failure of developing true educational theories (largely neglected since Hirst). Such theories, especially metatheories, could serve to reinforce science education’s growing sense of academic autonomy and independence from socio-economic demands. In Part II, I offer as a suggestion Egan’s cultural-linguistic theory as a metatheory to help resolve the impasse. I hope to make reformers familiar with his important ideas in general, and more specifically, to show how they can complement HPS rationales and reinforce the work of those researchers who have emphasized the value of narrative in learning science.

  9. Geography and environmental science

    OpenAIRE

    Milinčić, Miroljub; Souliotis, Lily; Mihajlović, Ljiljana; Požar, Tea

    2014-01-01

    Geography is one of the oldest academic disciplines with a strong holistic approach in conceptualizing the interaction between nature and society, i.e. animate and inanimate parts of the environment. Over time, geography has been increasing and improving its conceptual and terminological abilities for studying and understanding complex relationships among environmental systems. For this reason, geography has advanced from a well-known science about nature and society into a relevant science a...

  10. Symposium 1: Challenges in science education and popularization of Science

    Directory of Open Access Journals (Sweden)

    Ildeo de Castro Moreira

    2014-08-01

    Full Text Available Science education and popularization of science are important elements for social inclusion. The Brazil exhibits strong inequalities regarding the distribution of wealth, access to cultural assets and appropriation of scientific and technological knowledge. Each Brazilian should have the opportunity to acquire a basic knowledge of science and its operation that allow them to understand their environment and expand their professional opportunities. However, the overall performance of Brazilian students in science and math is bad. The basic science education has, most often, few resources and is discouraging, with little appreciation of experimentation, interdisciplinarity and creativity. Beside the shortage of science teachers, especially teachers with good formation, predominate poor wage and working conditions, and deficiencies in instructional materials and laboratories. If there was a significant expansion in access to basic education, the challenge remains to improve their quality. According to the last National Conference of STI, there is need of a profound educational reform at all levels, in particular with regard to science education. Already, the popularization of science can be an important tool for the construction of scientific culture and refinement of the formal teaching instrument. However, we still lack a comprehensive and adequate public policy to her intended. Clearly, in recent decades, an increase in scientific publication occurred: creating science centers and museums; greater media presence; use of the internet and social networks; outreach events, such as the National Week of CT. But the scenario is shown still fragile and limited to broad swathes of Brazilians without access to scientific education and qualified information on CT. In this presentation, from a general diagnosis of the situation, some of the main challenges related to education and popularization of science in the country will address herself.

  11. Research priorities in environmental education

    Science.gov (United States)

    George H. Moeller

    1977-01-01

    Although natural processes operate in urban areas, they are difficult to observe. Much discussion during the symposium-fair was devoted to finding ways to improve urban children's environmental understanding through environmental education programs. But before effective environmental education programs can be developed, research is needed to: test the...

  12. Innovation in Science Education - World-Wide.

    Science.gov (United States)

    Baez, Albert V.

    The purpose of this book is to promote improvements in science education, world-wide, but particularly in developing countries. It is addressed to those in positions to make effective contributions to the improvement of science education. The world-wide role of science education, the goals of innovative activities, past experience in efforts to…

  13. Feyerabend on Science and Education

    Science.gov (United States)

    Kidd, Ian James

    2013-01-01

    This article offers a sympathetic interpretation of Paul Feyerabend's remarks on science and education. I present a formative episode in the development of his educational ideas--the "Berkeley experience"--and describe how it affected his views on the place of science within modern education. It emerges that Feyerabend arrived at a…

  14. Collaborative Education in Climate Change Sciences and Adaptation through Interactive Learning

    Science.gov (United States)

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

    2014-12-01

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

  15. A successful programmatic structure and strategies to attract and educate students in earth and environmental sciences: an example from the University of Delaware, USA

    Science.gov (United States)

    Levia, Delphis

    2013-04-01

    The achievement of sustainable use of our natural world is one of the major issues confronting humankind today. Environmental issues are inherently complex and difficult to resolve. Successful resolution of our most pressing environmental problems, such as climate change and ocean acidification, will require well-trained earth and environmental scientists that think critically in a multi-dimensional framework at variable spatial and temporal scales. This begs the question as to how we can both attract and successfully educate students in such a way that will permit them to tackle the multitude of environmental problems currently facing society. This poster details one way to successfully attract and train students in an interdisciplinary environmental education framework by sharing: (1) some of the successful strategies and programmatic structure of the University of Delaware's undergraduate environmental programs that have grown over 60% in two years after a major programmatic revision; and (2) the current round of programmatic revisions that will complete the strategic planning process.* The interdisciplinary environmental education program at the University of Delaware has a strong programmatic core that provides students with the requisite quantitative training and field experience to solve complicated environmental issues. At the same time, the environmental program includes the social, political, and economic contexts of environmental issues. Together, these two parts of the core best equip students to mitigate environmental problems. Following a strategic planning effort, the University of Delaware is building upon past successes in training environmental scientists and managers by further reformulating its environmental programs to leverage the power of theme-based learning which complements the programmatic core in such a way to teach problem-solving skills. This poster details the multidimensional nature of the University of Delaware's environmental

  16. SSMA Science Reviewers' Forecasts for the Future of Science Education.

    Science.gov (United States)

    Jinks, Jerry; Hoffer, Terry

    1989-01-01

    Described is a study which was conducted as an exploratory assessment of science reviewers' perceptions for the future of science education. Arrives at interpretations for identified categories of computers and high technology, science curriculum, teacher education, training, certification, standards, teaching methods, and materials. (RT)

  17. The sustainability paradigm and the STS approach: mediations for science education

    Directory of Open Access Journals (Sweden)

    Elizandra Rêgo de Vasconcelos

    2012-12-01

    Full Text Available The society has been confronted with issues that involve interactions between science, technology and society (STS, which reveal social, economic, environmental, ethical implications, among others. The sustainability paradigm occupies a prominent position in this area. We understand that the STS guidelines are an important instrument for building the concept of sustainability in science education, whose perspectives consistent with the formation of citizens with environmental sensitivity-citizens who are able to analyze and evaluate critically issues related to the social, environmental and economic field, among other aspects. We propose, in this article, to discuss the possible links between the sustainability paradigm, the STS approach and the process of teaching and learning in science. This articulation certainly helps to think the implications of the current development model and the relationships STS, inserted, for example, on various issues, contexts, dimensions, knowledge and teaching strategies. Certainly, we must undertake the effort to approximate the natural and social fields, in the apprehension of the complex reality as it stands nowadays

  18. A strategy for global environmental education at the university

    International Nuclear Information System (INIS)

    Hussain, S.T.; Hayes, R.L.

    1993-01-01

    The Earth's environment is a dynamic system that is affected both by natural phenomena and by human activity. The changes occurring in the global environment are bound to have serious consequences for all its inhabitants. Therefore, the world is rapidly becoming interdependent. Multidisciplinary scientific efforts must be directed toward understanding these global environmental changes. These efforts will require sufficient funds to attract scientists into global environmental research and to disseminate new knowledge to future scholars and to the general public alike. The federal government has a definite role to play in this effort and should allocate sufficient funds to initiate and sustain these programs. Unfortunately, such funds are not currently budgeted. The academic department, as the basic structural and functional unit of the American university system, is most appropriate to ensure environmental educational goals. The authors propose the establishment of a novel Department of Global Environment at every university. That department must be multidisciplinary in nature and must accumulate a critical mass of scholars from all relevant traditional disciplines in the arts and sciences to generate knowledge, to educate students, and to provide advisory services to policy makers. The study product of this department should receive a broad-based education and should emerge as an informed individual who possesses sufficient skills to achieve sustainable communities. That student should also be equipped to assume leadership and to formulate policy about global environmental issues. The investment in education may well be the only way to secure a future for humanity and for the natural world as we now know it

  19. Fermilab Friends for Science Education | Join Us

    Science.gov (United States)

    Fermilab Friends for Science Education FFSE Home About Us Join Us Support Us Contact Us Join Us improving science (science, technology, engineering and mathematics) education. Your donation allows us to membership dues allow us to create new, innovative science education programs, making the best use of unique

  20. Basic science right, not basic science lite: medical education at a crossroad.

    Science.gov (United States)

    Fincher, Ruth-Marie E; Wallach, Paul M; Richardson, W Scott

    2009-11-01

    This perspective is a counterpoint to Dr. Brass' article, Basic biomedical sciences and the future of medical education: implications for internal medicine. The authors review development of the US medical education system as an introduction to a discussion of Dr. Brass' perspectives. The authors agree that sound scientific foundations and skill in critical thinking are important and that effective educational strategies to improve foundational science education should be implemented. Unfortunately, many students do not perceive the relevance of basic science education to clinical practice.The authors cite areas of disagreement. They believe it is unlikely that the importance of basic sciences will be diminished by contemporary directions in medical education and planned modifications of USMLE. Graduates' diminished interest in internal medicine is unlikely from changes in basic science education.Thoughtful changes in education provide the opportunity to improve understanding of fundamental sciences, the process of scientific inquiry, and translation of that knowledge to clinical practice.

  1. Hands-on science: science education with and for society

    OpenAIRE

    Costa, Manuel F. M., ed. lit.; Pombo, José Miguel Marques, ed. lit.; Vázquez Dorrío, José Benito, ed. lit.

    2014-01-01

    The decisive importance of Science on the development of modern societies gives Science Education a role of special impact. Society sets the requirements rules and procedures of Education defining what concepts and competencies citizens must learn and how this learning should take place. Educational policies set by governments, elected and or imposed, not always reflects the will and ruling of Society. The School as pivotal element of our modern educational system must look ...

  2. Education for Sustainable Living: An International Perspective on Environmental Education.

    Science.gov (United States)

    Fien, John

    1993-01-01

    Analyzes the nature of sustainable development and the role that environmental education can play in a transformation toward a sustainable society. Discusses three rules for teaching environmental education: a child-centered education, objectivity on matters of values, and creation of environmentally responsible behavior. Provides a checklist of…

  3. Transforming Elementary Science Teacher Education by Bridging Formal and Informal Science Education in an Innovative Science Methods Course

    Science.gov (United States)

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

    2011-01-01

    We investigated curricular and pedagogical innovations in an undergraduate science methods course for elementary education majors at the University of Maryland. The goals of the innovative elementary science methods course included: improving students' attitudes toward and views of science and science teaching, to model innovative science teaching…

  4. Educational needs of family physicians in the domains of health and conformity with continuing education in Fasa University of Medical Sciences.

    Science.gov (United States)

    Zarif Sanaiey, Nahid; Karamnejad, Sahar; Rezaee, Rita

    2015-04-01

    Assessment and prioritization are the first steps of planning. According to the family physician's idea, evaluating programs in order to improve them is one of the necessities of promoting quality and increases the efficiency and effectiveness of continuing education. This study aimed to determine family physicians' educational needs regarding health and its applicability in continuous medical education in Fasa University of Medical Sciences. In this cross-sectional study, viewpoints of 45 general physicians working at Fasa University of Medical Sciences in 2013 were studied. Samples were selected through census. Data collection was done using a researcher-made questionnaire using 10-point Likert scale and a checklist with Delphi technique.  Content validity of the questionnaire and its reliability were confirmed by the experts' opinion and Cronbach's alpha of 80%.  The data were analyzed through SPSS software version 16, using both descriptive and inferential statistics (mean and standard deviation, standard score (SQ), t-test, ANOVAs). A significance level of mental health (SQ= 0.38), and environmental and professional health was the lowest priority (SQ= _0.24). Additionally, within each of the areas above specific priorities were determined. Based on the results of this study, gender, graduation date, cooperation time, and university they were educated in did not affect expressing educational needs (p>0.05). The most educational conformity with continuing education was in the diseases area (topic 27%, content 37%). In the areas of environmental and professional health and health education, compliance was zero. The physicians stated that mental health was the first educational need and environmental and professional health was the last one. According to the results, proper continuing medical programs should be coordinated with educational needs.

  5. Sense of Place in Environmental Education

    Science.gov (United States)

    Kudryavtsev, Alex; Stedman, Richard C.; Krasny, Marianne E.

    2012-01-01

    Although environmental education research has embraced the idea of sense of place, it has rarely taken into account environmental psychology-based sense of place literature whose theory and empirical studies can enhance related studies in the education context. This article contributes to research on sense of place in environmental education from…

  6. Environmental Education and Sustainability: Reflections in a Management Context

    Directory of Open Access Journals (Sweden)

    Leandro Petarnella

    2017-05-01

    Full Text Available This study aims to reflect and discuss on Environmental Education (EE and Sustainability Education in Management, particularly stricto sensu Postgraduate Programmes. For this, it studies the history and the subject longevity in its transience, therefore it is a review article. This study was conducted through an exploratory approach, with a qualitative method of inductive reasoning, based on literature and document review for conceptual appropriation. Its relevance addresses two inter, multi and transdisciplinary issues, which reveal and complement each other in a broader social understanding. The reflections here discussed under the administration context, point to the challenge of the respective area. This should devise and disseminate scientific knowledge from and related to management that can operate under changes in the current social paradigm in which this science is linked to the others paradigm that is expected in the future: management contextualized and articulated with the sustainability paradigm. The study’s conclusion is that the challenge of incorporating sustainability into the teaching of stricto sensu Postgraduation in Management should be addressed through environmental education.

  7. The impact of socio-political environment on the perception of science - a comparative study of German and Israeli approaches to science education

    Science.gov (United States)

    Schneider, S.; Rabinowitz, D.

    2017-12-01

    At the interface of environmental anthropology, social science, education research, and Earth Sciences, this presentation will look at Earth science education in school and out-of-school settings in Germany and Israel. We will focus on divergent cultural concepts of nature and science within the four-columned societal system in Israel: the secular Israeli community, which is oriented on western standards and concepts, the orthodox community with a stronger focus on merging scientific and religious approaches to understanding the Earth system, the Arabian community in Israel, which is strongly influenced by the Arabian science tradition as well as by confined monetary resources, and the ultra-orthodox community where science education seems to be totally abandoned in favor of Thora-studies. These environments, alongside a more homogeneous Germany educational system, resample an experimental setting with differences in a manageable number of parameters. We will analyze educational material used by the different communities in terms of the presented functions and services of the Earth sciences as well as in respect to the image of Earth sciences constructed by educational material of the observed communities. The aim of this project is to look for evidence that allows to attribute significant differences in education concepts to formal socio-political settings in the observed communities. The term Socio-political environment as used in this project proposal describes the context that is predetermined by cultural, political, and religious traditions. It described the pre-conditions in which communication takes place. Within this presentation, we will discuss the concept of socio-political environments. One of our hypothesis is, that the intensity of differences in Earth science community will be associated with differences in the socio-political environment. Influences of cultural, political, and religious boundary conditions will provide an insight into alterations

  8. Fermilab Friends for Science Education | Programs

    Science.gov (United States)

    Fermilab Friends for Science Education FFSE Home About Us Join Us Support Us Contact Us Programs Donors Board of Directors Board Tools Calendar Join Us Donate Now Get FermiGear! Education Office Search photo Fermilab Friends for Science Education, in partnership with Fermilab and area educators, designs

  9. The nature of science in science education: theories and practices

    Directory of Open Access Journals (Sweden)

    Ana Maria Morais

    2018-01-01

    Full Text Available The article is based on results of research carried out by the ESSA Group (Sociological Studies of the Classroom centred on the inclusion of the nature of science (metascience on science education. The results, based on analyses of various educational texts and contexts – curricula/syllabuses, textbooks and pedagogic practices – and of the relations between those texts/contexts, have in general shown a reduced presence and low conceptualization of metascience. The article starts by presenting the theoretical framework of the research of the ESSA Group which was focused on the introduction of the nature of science in science education. It is mostly based on Ziman’s conceptualization of metascience (1984, 2000 and on Bernstein’s theorization of production and reproduction of knowledge, particularly his model of pedagogic discourse (1990, 2000 and knowledge structures (1999. This is followed by the description of a pedagogical strategy, theoretically grounded, which explores the nature of science in the classroom context. The intention is to give an example of a strategy which privileges a high level learning for all students and which may contribute to a reflection about the inclusion of the nature of science on science education. Finally, considerations are made about the applicability of the strategy on the basis of previous theoretical and empirical arguments which sustain its use in the context of science education.

  10. Critical materialism: science, technology, and environmental sustainability.

    Science.gov (United States)

    York, Richard; Clark, Brett

    2010-01-01

    There are widely divergent views on how science and technology are connected to environmental problems. A view commonly held among natural scientists and policy makers is that environmental problems are primarily technical problems that can be solved via the development and implementation of technological innovations. This technologically optimistic view tends to ignore power relationships in society and the political-economic order that drives environmental degradation. An opposed view, common among postmodernist and poststructuralist scholars, is that the emergence of the scientific worldview is one of the fundamental causes of human oppression. This postmodernist view rejects scientific epistemology and often is associated with an anti-realist stance, which ultimately serves to deny the reality of environmental problems, thus (unintentionally) abetting right-wing efforts to scuttle environmental protection. We argue that both the technologically optimistic and the postmodernist views are misguided, and both undermine our ability to address environmental crises. We advocate the adoption of a critical materialist stance, which recognizes the importance of natural science for helping us to understand the world while also recognizing the social embeddedness of the scientific establishment and the need to challenge the manipulation of science by the elite.

  11. New concepts of science and medicine in science and technology studies and their relevance to science education.

    Science.gov (United States)

    Wang, Hsiu-Yun; Stocker, Joel F; Fu, Daiwie

    2012-02-01

    Science education often adopts a narrow view of science that assumes the lay public is ignorant, which seemingly justifies a science education limited to a promotional narrative of progress in the form of scientific knowledge void of meaningful social context. We propose that to prepare students as future concerned citizens of a technoscientific society, science education should be informed by science, technology, and society (STS) perspectives. An STS-informed science education, in our view, will include the following curricular elements: science controversy education, gender issues, historical perspective, and a move away from a Eurocentric view by looking into the distinctive patterns of other regional (in this case of Taiwan, East Asian) approaches to science, technology, and medicine. This article outlines the significance of some major STS studies as a means of illustrating the ways in which STS perspectives can, if incorporated into science education, enhance our understanding of science and technology and their relationships with society. Copyright © 2011. Published by Elsevier B.V.

  12. New concepts of science and medicine in science and technology studies and their relevance to science education

    Directory of Open Access Journals (Sweden)

    Hsiu-Yun Wang

    2012-02-01

    Full Text Available Science education often adopts a narrow view of science that assumes the lay public is ignorant, which seemingly justifies a science education limited to a promotional narrative of progress in the form of scientific knowledge void of meaningful social context. We propose that to prepare students as future concerned citizens of a technoscientific society, science education should be informed by science, technology, and society (STS perspectives. An STS-informed science education, in our view, will include the following curricular elements: science controversy education, gender issues, historical perspective, and a move away from a Eurocentric view by looking into the distinctive patterns of other regional (in this case of Taiwan, East Asian approaches to science, technology, and medicine. This article outlines the significance of some major STS studies as a means of illustrating the ways in which STS perspectives can, if incorporated into science education, enhance our understanding of science and technology and their relationships with society.

  13. Project of international science-education center and integration problems of nano science education in far eastern region of Asia

    International Nuclear Information System (INIS)

    Plusnin, N I; Lazarev, G I

    2008-01-01

    Some conception of international science-education center on nano science in Vladivostok is presented. The conception is based on internal and external prerequisites. Internal one is high intellectual potential of institutes of Russian Academy of Sciences and universities of Vladivostok and external one is need of countries of Far Eastern region of Asia in high level manpower. The conception takes into account a specific distribution of science and education potential between Russian Academy of Sciences and Russian universities and a specific their dislocation in Vladivostok. First specific dictates some similarity of organization structure and function of international science-education center to typical science-education center in Russia. But as for dislocation of the international science-education center in Vladivostok, it should be near dislocation of institutes of Far Eastern Brunch of Russian Academy of Sciences in Vladivostok, which are dislocated very compactly in suburb zone of Vladivostok

  14. Journal of Applied Sciences and Environmental Management - Vol ...

    African Journals Online (AJOL)

    Journal of Applied Sciences and Environmental Management. ... AFRICAN JOURNALS ONLINE (AJOL) · Journals · Advanced Search · USING ... Journal of Applied Sciences and Environmental Management - Vol 22, No 5 (2018) .... Growth Performance of Five Bean (Phaseolus spp) Varieties as Influenced by Organic ...

  15. Guidelines for Building Science Education

    Energy Technology Data Exchange (ETDEWEB)

    Metzger, Cheryn E. [Pacific Northwest National Lab. (PNNL), Richland, WA (United States); Rashkin, Samuel [Pacific Northwest National Lab. (PNNL), Richland, WA (United States); Huelman, Pat [Pacific Northwest National Lab. (PNNL), Richland, WA (United States)

    2015-11-01

    The U.S. Department of Energy’s (DOE) residential research and demonstration program, Building America, has triumphed through 20 years of innovation. Partnering with researchers, builders, remodelers, and manufacturers to develop innovative processes like advanced framing and ventilation standards, Building America has proven an energy efficient design can be more cost effective, healthy, and durable than a standard house. As Building America partners continue to achieve their stretch goals, they have found that the barrier to true market transformation for high performance homes is the limited knowledge-base of the professionals working in the building industry. With dozens of professionals taking part in the design and execution of building and selling homes, each person should have basic building science knowledge relevant to their role, and an understanding of how various home components interface with each other. Instead, our industry typically experiences a fragmented approach to home building and design. After obtaining important input from stakeholders at the Building Science Education Kick-Off Meeting, DOE created a building science education strategy addressing education issues preventing the widespread adoption of high performance homes. This strategy targets the next generation and provides valuable guidance for the current workforce. The initiative includes: • Race to Zero Student Design Competition: Engages universities and provides students who will be the next generation of architects, engineers, construction managers and entrepreneurs with the necessary skills and experience they need to begin careers in clean energy and generate creative solutions to real world problems. • Building Science to Sales Translator: Simplifies building science into compelling sales language and tools to sell high performance homes to their customers. • Building Science Education Guidance: Brings together industry and academia to solve problems related to

  16. Narrative Inquiry for Science Education: Teachers' repertoire-making in the case of environmental curriculum

    Science.gov (United States)

    Hwang, Seyoung

    2011-04-01

    This paper considers how the school science curriculum can be conceptualised in order to address the contingent and complex nature of environmental and sustainability-related knowledge and understanding. A special concern lies in the development of research perspectives and tools for investigating ways, in which teachers are faced with complex and various situations in the sense-making of science-related issues, and subsequent pedagogic issues. Based on an empirical examination of Korean teachers' sense-making of their curricular practice, the paper develops a narrative approach to teachers' perspectives and knowledge by considering the value of stories as sense-making tools for reflective questioning of what is worth teaching, how and why. By employing the idea of 'repertoire', the study regards teachers' stories about their environment-related personal and teaching experiences as offering angles with which to understand teachers' motivation and reflection in curricular development and implementation. Furthermore, three empirical cases present ways in which the nature of knowledge and understanding is recognised and potentially integrated into pedagogies through teachers' narratives. Finally, the paper argues for the need to reconsider the role of the science teacher in addressing environmental and sustainability-related issues, in ways that facilitate teachers' reflexive interpretation of meanings in cultural texts and the construction of pedagogic text.

  17. An Environmental Ethical Conceptual Framework for Research on Sustainability and Environmental Education

    Science.gov (United States)

    Kronlid, David O.; Ohman, Johan

    2013-01-01

    This article suggests that environmental ethics can have great relevance for environmental ethical content analyses in environmental education and education for sustainable development research. It is based on a critique that existing educational research does not reflect the variety of environmental ethical theories. Accordingly, we suggest an…

  18. University Science and Mathematics Education in Transition

    DEFF Research Database (Denmark)

    Skovsmose, Ole; Valero, Paola; Christensen, Ole Ravn

    configuration poses to scientific knowledge, to universities and especially to education in mathematics and science. Traditionally, educational studies in mathematics and science education have looked at change in education from within the scientific disciplines and in the closed context of the classroom....... Although educational change is ultimately implemented in everyday teaching and learning situations, other parallel dimensions influencing these situations cannot be forgotten. An understanding of the actual potentialities and limitations of educational transformations are highly dependent on the network...... of educational, cultural, administrative and ideological views and practices that permeate and constitute science and mathematics education in universities today. University Science and Mathematics Education in Transition contributes to an understanding of the multiple aspects and dimensions of the transition...

  19. Journal of Applied Sciences and Environmental Management - Vol ...

    African Journals Online (AJOL)

    Journal of Applied Sciences and Environmental Management. ... AFRICAN JOURNALS ONLINE (AJOL) · Journals · Advanced Search · USING ... Journal of Applied Sciences and Environmental Management - Vol 22, No 4 (2018) ... Evaluating the effect of mobility speed on the performance of three handover algorithms in ...

  20. Educational Technology Classics: The Science Teacher and Educational Technology

    Science.gov (United States)

    Harbeck, Richard M.

    2015-01-01

    The science teacher is the key person who has the commitment and the responsibility for carrying out any brand of science education. All of the investments, predictions, and expressions of concern will have little effect on the accomplishment of the broad goals of science education if these are not reflected in the situations in which learning…

  1. Postparadigmatic Materialisms: A "New Movement of Thought" for Outdoor Environmental Education Research?

    Science.gov (United States)

    Gough, Noel

    2016-01-01

    Since at least the beginning of this century, the literatures of research methodology in the social sciences have increasingly focused on what are now being called "new empiricisms" and "new materialisms." My purpose in this essay is to appraise the potential of these approaches for outdoor environmental education research. I…

  2. Bioremediation Education Science and Technology (BEST) Program Annual Report 1999

    Energy Technology Data Exchange (ETDEWEB)

    Hazen, Terry C.

    2000-07-01

    The Bioremediation, Education, Science and Technology (BEST) partnership provides a sustainable and contemporary approach to developing new bioremedial technologies for US Department of Defense (DoD) priority contaminants while increasing the representation of underrepresented minorities and women in an exciting new biotechnical field. This comprehensive and innovative bioremediation education program provides under-represented groups with a cross-disciplinary bioremediation cirruculum and financial support, coupled with relevant training experiences at advanced research laboratories and field sites. These programs are designed to provide a stream of highly trained minority and women professionals to meet national environmental needs.

  3. The feasibility of educating trainee science teachers in issues of science and religion

    Science.gov (United States)

    Poole, Michael

    2016-06-01

    This article reflects on Roussel De Carvalho's paper `Science initial teacher education and superdiversity: educating science teachers for a multi-religious and globalized science classroom'. It then offers suggestions for making some of the ambitious goals of the science-and-religion components of the science initial teacher education project more manageable.

  4. Education science and biological anthropology.

    Science.gov (United States)

    Krebs, Uwe

    2014-01-01

    This contribution states deficits and makes proposals in order to overcome them. First there is the question as to why the Biological Anthropology--despite all its diversifications--hardly ever deals with educational aspects of its subject. Second it is the question as to why Educational Science neglects or even ignores data of Biological Anthropology which are recognizably important for its subject. It is postulated that the stated deficits are caused by several adverse influences such as, the individual identity of each of the involved single sciences; aspects of the recent history of the German Anthropology; a lack of conceptual understanding of each other; methodological differences and, last but not least, the structure of the universities. The necessity to remedy this situation was deduced from two groups of facts. First, more recent data of the Biological Anthropology (e.g. brain functions and learning, sex specificity and education) are of substantial relevance for the Educational Science. Second, the epistemological requirements of complex subjects like education need interdisciplinary approaches. Finally, a few suggestions of concrete topics are given which are related to both, Educational Science and Biological Anthropology.

  5. Research trends and issues in informal science education

    Science.gov (United States)

    Pinthong, Tanwarat; Faikhamta, Chatree

    2018-01-01

    Research in informal science education (ISE) become more interesting area in science education for a few decades. The main purpose of this research is to analyse research articles in 30 issues of top three international journals in science education; Journal of Research in Science Teaching, Science Education, and the International Journal of Science Education. The research articles during 2007 and 2016 were reviewed and analysed according to the authors' nationality, informal science education's research topics, research paradigms, methods of data collection and data analysis. The research findings indicated that there were 201 published papers related to informal science education, successfully submitted by 469 authors from 27 different countries. In 2008, there was no article related to informal science education. Statistical analyses showed that authors from USA are the most dominant, followed by UK and Israel. The top three ISE's research topics most frequently investigated by the researchers were regarding students' informal learning, public understanding in science, and informal perspectives, policies and paradigms. It is also found that theoretical framework used in informal science education which is becoming more strongly rooted is in a mix of the sociocultural and constructivist paradigms, with a growing acceptance of qualitative research methods and analyses.

  6. Beyond Science and Technology: The need to incorporate Environmental Ethics to solve Environmental Problems

    Directory of Open Access Journals (Sweden)

    Fesseha Mulu

    2018-01-01

    Full Text Available The emergence and development of science and technology has been critical in improving the lives of mankind. It helps mankind to cope with a number of manmade and natural challenges and disasters. Science cannot totally diminish the level of human dependency on nature; but, with the existing availability of natural resources, science has increased our productivity. However, science and technology can also have its own negative impacts on the natural environment. For the purpose of increasing productivity and satisfying human needs, humans have been egoistically exploiting nature but disregarding the effects of their activities on nature. Science has also been trying its level best to mitigate the negative effects that results from mankind’s exploitation of nature. However, science alone is incapable of solving all environmental problems. This desk research employs secondary sources of data, and argues that environmental ethics should come to the fore in order to address the gap left by science with regard to resolving environmental problems that mankind faces today.

  7. Improving science literacy and education through space life sciences

    Science.gov (United States)

    MacLeish, M. Y.; Moreno, N. P.; Tharp, B. Z.; Denton, J. J.; Jessup, G.; Clipper, M. C.

    2001-01-01

    The National Space Biomedical Research Institute (NSBRI) encourages open involvement by scientists and the public at large in the Institute's activities. Through its Education and Public Outreach Program, the Institute is supporting national efforts to improve Kindergarten through grade twelve (K-12) and undergraduate education and to communicate knowledge generated by space life science research to lay audiences. Three academic institution Baylor College of Medicine, Morehouse School of Medicine and Texas A&M University are designing, producing, field-testing, and disseminating a comprehensive array of programs and products to achieve this goal. The objectives of the NSBRI Education and Public Outreach program are to: promote systemic change in elementary and secondary science education; attract undergraduate students--especially those from underrepresented groups--to careers in space life sciences, engineering and technology-based fields; increase scientific literacy; and to develop public and private sector partnerships that enhance and expand NSBRI efforts to reach students and families. c 2001. Elsevier Science Ltd. All rights reserved.

  8. 76 FR 11765 - Education Research and Special Education Research Grant Programs; Institute of Education Sciences...

    Science.gov (United States)

    2011-03-03

    ... DEPARTMENT OF EDUCATION Education Research and Special Education Research Grant Programs; Institute of Education Sciences; Overview Information; Education Research and Special Education Research.... SUMMARY: The Director of the Institute of Education Sciences (Institute) announces the Institute's FY 2012...

  9. Educational needs of family physicians in the domains of health and conformity with continuing education in Fasa University of Medical Sciences

    Directory of Open Access Journals (Sweden)

    NAHID ZARIF SANAIEY

    2015-04-01

    Full Text Available Introduction: Assessment and prioritization are the first steps of planning. According to the family physician’s idea, evaluating programs in order to improve them is one of the necessities of promoting quality and increases the efficiency and effectiveness of continuing education. This study aimed to determine family physicians’ educational needs regarding health and its applicability in continuous medical education in Fasa University of Medical Sciences. Methods: In this cross-sectional study, viewpoints of 45 general physicians working at Fasa University of Medical Sciences in 2013 were studied. Samples were selected through census. Data collection was done using a researcher-made questionnaire using 10-point Likert scale and a checklist with Delphi technique. Content validity of the questionnaire and its reliability were confirmed by the experts’ opinion and Cronbach’s alpha of 80%. The data were analyzed through SPSS software version 16, using both descriptive and inferential statistics (mean and standard deviation, standard score (SQ, t-test, ANOVAs. A significance level of 0.05. The most educational conformity with continuing education was in the diseases area (topic 27%, content 37%. In the areas of environmental and professional health and health education, compliance was zero. Conclusions: The physicians stated that mental health was the first educational need and environmental and professional health was the last one. According to the results, proper continuing medical programs should be coordinated with educational needs.

  10. Research report 1987-1989: Environmental Quality Laboratory and Environmental Engineering Science, W. M. Keck Laboratories

    OpenAIRE

    Brooks, Norman H.

    1990-01-01

    This research biennial report for 1987-89 covers the activities of both the Environmental Engineering Science program and the Environmental Quality Laboratory for the period October 1987-November 1989. Environmental Engineering Science is the degree-granting academic program housed in the Keck Laboratories, with associated research projects. The Environmental Quality Laboratory is a research center focusing on large scale problems of environmental quality and natural resources. All the facult...

  11. Concepts of matter in science education

    CERN Document Server

    Sevian, Hannah

    2013-01-01

    Bringing together a wide collection of ideas, reviews, analyses and new research on particulate and structural concepts of matter, Concepts of Matter in Science Education informs practice from pre-school through graduate school learning and teaching and aims to inspire progress in science education. The expert contributors offer a range of reviews and critical analyses of related literature and in-depth analysis of specific issues, as well as new research. Among the themes covered are learning progressions for teaching a particle model of matter, the mental models of both students and teachers of the particulate nature of matter, educational technology, chemical reactions and chemical phenomena, chemical structure and bonding, quantum chemistry and the history and philosophy of science relating to the particulate nature of matter. The book will benefit a wide audience including classroom practitioners and student teachers at every educational level, teacher educators and researchers in science education.

  12. Tipping Points and Balancing Acts: Grand Challenges and Synergistic Opportunities of Integrating Research and Education, Science and Solutions

    Science.gov (United States)

    McCaffrey, M. S.; Stroeve, J. C.

    2011-12-01

    The "Grand Challenges" to address Global Change identified by the International Council for Science (ICSU) and its partners through the Earth System Sustainability Initiative-improving forecasting, enhancing and integrating observation systems, confining and minimizing global environmental change, responding effectively to change, as well as innovating and evaluating these efforts-require an integrative approach that engages and inspires society in general and young people in particular. What are some of the effective strategies-and stumbling blocks-in being able to make Earth System science and related sustainability efforts relevant and practical to non-technical audiences? Recent climate education projects have pioneered new strategies toward linking and infusing research with education, science with solutions. For example, the Climate Literacy and Energy Awareness Network (CLEAN), a National Science Digital Library Pathway funded by NSF, has approached this integral approach by "closing the loop" between climate and energy topics, identifying and annotating high quality online resources relating to the carbon cycle and related topics. The Inspiring Climate Education Excellence (ICEE) project, funded by NASA, offers professional development for teachers that infuses climate science with solutions as an emerging "best practice" while being sensitive to the emotional, psychological and political aspects of avoiding "gloom and doom" on one hand or advocating for particular policy solutions on another. Other examples includes NASA's climate website (http://climate.nasa.gov ), which serves as a robust, engaging portal for climate research and data, especially for educators. The recent PBS series Earth: The Operators' Manual and related book and website are other recent example of how climate science research, education and solutions can be incorporated in a way that is appealing and informative. The Alliance for Climate Education (ACE) has given assemblies in

  13. Timeline: environmental education in Colombia

    Directory of Open Access Journals (Sweden)

    Luz Adriana Pita-Morales

    2016-12-01

    Full Text Available The environmental education is a process that allows the individual to understand the relations of interdependence with the environment in the one that develops, is like that, since the reality bears biophysics in mind, social, political, economic in this respect it is necessary to generate in the company activities of valuation and respect for the environment. The environmental education is a dynamic and participative process orientated to the formation of critical and reflexive persons with aptitude to understand the environmental problematics of the local, regional and national context. In this frame the need is born of contextualized the labor that has become national in the construction of instruments that allow him the condition to look at the environmental education as a fundamental tool for the care of the natural resources and not as an isolated concept foreign to the community. In the present review their approaches the historical frame of the environmental education in Colombia his challenges, challenges and the way like are opening formative spaces and of projection for the suitable managing of the environment. In conclusion environmental education is a participatory process that must be born of the group in order to give management the natural resources of a region and community where professionals to do is oriental these processes in society.

  14. Integrating Climate Change Science and Sustainability in Environmental Science, Sociology, Philosophy and Business Courses.

    Science.gov (United States)

    Boudrias, M. A.; Cantzler, J.; Croom, S.; Huston, C.; Woods, M.

    2015-12-01

    Courses on sustainability can be taught from multiple perspectives with some focused on specific areas (environmental, socio-cultural, economic, ethics) and others taking a more integrated approach across areas of sustainability and academic disciplines. In conjunction with the Climate Change Education Program efforts to enhance climate change literacy with innovative approaches, resources and communication strategies developed by Climate Education Partners were used in two distinct ways to integrate climate change science and impacts into undergraduate and graduate level courses. At the graduate level, the first lecture in the MBA program in Sustainable Supply Chain Management is entirely dedicated to climate change science, local and global impacts and discussions about key messages to communicate to the business community. Basic science concepts are integrated with discussions about mitigation and adaptation focused on business leaders. The concepts learned are then applied to the semester-long business plan project for the students. At the undergraduate level, a new model of comprehensive integration across disciplines was implemented in Spring 2015 across three courses on Sustainability each with a specific lens: Natural Science, Sociology and Philosophy. All three courses used climate change as the 'big picture' framing concept and had similar learning objectives creating a framework where lens-specific topics, focusing on depth in a discipline, were balanced with integrated exercises across disciplines providing breadth and possibilities for integration. The comprehensive integration project was the creation of the climate action plan for the university with each team focused on key areas of action (water, energy, transportation, etc.) and each team built with at least one member from each class ensuring a natural science, sociological and philosophical perspective. The final project was presented orally to all three classes and an integrated paper included

  15. Environmental health science at the U.S. Geological Survey

    Science.gov (United States)

    Buxton, Herbert T.; Bright, Patricia R.

    2013-01-01

    USGS environmental health science focuses on the environment-health interface. Research characterizes the processes that affect the interaction among the physical environment, the living environment, and people, as well as the factors that affect ecological and human exposure to disease agents and the resulting toxicologic or infectious disease. The mission of USGS in environmental health science is to contribute scientific information to environmental, natural resource, agricultural, and public-health managers, who use that information to support sound decisionmaking. Coordination with partners and stakeholders will enable USGS to focus on the highest priority environmental health issues, to make relevant, timely, and useable contributions, and to become a “partner of first choice” for environmental health science.

  16. Science during crisis: the application of social science during major environmental crises

    Science.gov (United States)

    Machlis, Gary; Ludwig, Kris; Manfredo, Michael J.; Vaske, Jerry J.; Rechkemmer, Andreas; Duke, Esther

    2014-01-01

    Historical and contemporary experience suggests that science plays an increasingly critical role in governmental and institutional responses to major environmental crises. Recent examples include major western wildfires (2009), the Deepwater Horizon oil spill (2010), the Fukushima nuclear accident (2011), and Hurricane Sandy (2012). The application of science during such crises has several distinctive characteristics, as well as essential requirements if it is to be useful to decision makers. these include scope conditions that include coupled natural/human systems, clear statement of uncertainties and limitations, description of cascading consequences, accurate sense of place, estimates of magnitude of impacts, identification of beneficiaries and those adversely affected, clarity and conciseness, compelling visualization and presentation, capacity to speak "truth to power", and direct access to decision makers. In this chapter, we explore the role and significance of science – including all relevant disciplines and focusing attention on the social sciences – in responding to major environmental crises. We explore several important questions: How is science during crisis distinctive? What social science is most useful during crises? What distinctive characteristics are necessary for social science to make meaningful contributions to emergency response and recovery? How might the social sciences be integrated into the strategic science needed to respond to future crises? The authors, both members of the Department of the Interior's innovative Strategic Sciences Group, describe broad principles of engagement as well as specific examples drawn from history, contemporary efforts (such as during the Deepwater Horizon oil spill), and predictions of environmental crises still to be confronted.

  17. Environmental education in an Egyptian university: The role of teacher educators

    Science.gov (United States)

    Goueli, Solafa

    Drawing on a holistic critical paradigm of ecological sustainability, this study examined the role of teacher educators in environmental education in the Faculty of Education of one Egyptian university. The study sought to critically and collaboratively explore with a sample of six teacher educators their answers, perceptions and perspectives in relation to their knowledge and understanding of environmental problems in local/global contexts and their meanings of curriculum and pedagogical practices for fostering environmental education in their teacher education programs. The participants generally demonstrated a considerable amount of knowledge of the environmental realities and problems facing Egypt encompassing air, water and solid waste sectors. Their views concurred with national and official studies identifying these issues as the most pressing environmental problems in the country. The exploration of the institutional, social and cultural causes and developmental and/or global causes of environmental problems in Egypt led us to articulate different themes relating environmental crisis in Egypt to different issues. These issues included poverty, education, religion and development. One of the major findings of the study was the participants' view that development was the major contributor to the environmental crisis in Egypt. They all stressed that, in its pursuit of economic growth, the government did not pay due attention to the environmental costs. Sharing perspectives from a critical paradigm of ecological sustainability, the participants felt that the government needed to clearly address the economic and ecological dimensions of development. In addition, a few participants affirmed that development is the thread that ties all the different factors together bringing into the conversations other dimensions of development like the social, values, and political dimensions. Addressing the future dimension of development, all of them expressed the need for a

  18. Science, Worldviews, and Education

    Science.gov (United States)

    Gauch, Hugh G., Jr.

    2009-01-01

    Whether science can reach conclusions with substantial worldview import, such as whether supernatural beings exist or the universe is purposeful, is a significant but unsettled aspect of science. For instance, various scientists, philosophers, and educators have explored the implications of science for a theistic worldview, with opinions spanning…

  19. Fermilab Friends for Science Education | Support Us

    Science.gov (United States)

    Fermilab Friends for Science Education FFSE Home About Us Join Us Support Us Contact Us Support Us improving science (science, technology, engineering and mathematics) education. Your donation allows us to Testimonials Our Donors Board of Directors Board Tools Calendar Join Us Donate Now Get FermiGear! Education

  20. 75 FR 13265 - National Board for Education Sciences

    Science.gov (United States)

    2010-03-19

    ... DEPARTMENT OF EDUCATION National Board for Education Sciences AGENCY: Institute of Education Sciences, Department of Education. ACTION: Notice of an open meeting. SUMMARY: This notice sets forth the schedule and proposed agenda of an upcoming meeting of the National Board for Education Sciences. The...

  1. 75 FR 53280 - National Board for Education Sciences

    Science.gov (United States)

    2010-08-31

    ... DEPARTMENT OF EDUCATION National Board for Education Sciences AGENCY: Department of Education, Institute of Education Sciences. ACTION: Notice of an open meeting. SUMMARY: This notice sets forth the schedule and proposed agenda of an upcoming meeting of the National Board for Education Sciences. The...

  2. Evaluation of Students' Energy Conception in Environmental Science

    Science.gov (United States)

    Park, Mihwa; Johnson, Joseph A.

    2016-01-01

    While significant research has been conducted on students' conceptions of energy, alternative conceptions of energy have not been actively explored in the area of environmental science. The purpose of this study is to examine students' alternative conceptions in the environmental science discipline through the analysis of responses of first year…

  3. Emotions in teaching environmental science

    Science.gov (United States)

    Quigley, Cassie

    2016-09-01

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

  4. The Nature of Science and Science Education: A Bibliography

    Science.gov (United States)

    Bell, Randy; Abd-El-Khalick, Fouad; Lederman, Norman G.; Mccomas, William F.; Matthews, Michael R.

    Research on the nature of science and science education enjoys a long history, with its origins in Ernst Mach's work in the late nineteenth century and John Dewey's at the beginning of the twentieth century. As early as 1909 the Central Association for Science and Mathematics Teachers published an article - A Consideration of the Principles that Should Determine the Courses in Biology in Secondary Schools - in School Science and Mathematics that reflected foundational concerns about science and how school curricula should be informed by them. Since then a large body of literature has developed related to the teaching and learning about nature of science - see, for example, the Lederman (1992)and Meichtry (1993) reviews cited below. As well there has been intense philosophical, historical and philosophical debate about the nature of science itself, culminating in the much-publicised Science Wars of recent time. Thereferences listed here primarily focus on the empirical research related to the nature of science as an educational goal; along with a few influential philosophical works by such authors as Kuhn, Popper, Laudan, Lakatos, and others. While not exhaustive, the list should prove useful to educators, and scholars in other fields, interested in the nature of science and how its understanding can be realised as a goal of science instruction. The authors welcome correspondence regarding omissions from the list, and on-going additions that can be made to it.

  5. Planning and implementing an honors degree in environmental science curricula: a case study from the University of Delaware, USA

    Science.gov (United States)

    Levia, Delphis

    2015-04-01

    Environmental degradation is undermining the sustainability of our planet. The multi-faceted nature of environmental stressors, which inherently couples human-environment interactions across space and time, necessitates that we train environmental scientists holistically within an interdisciplinary framework. Recruiting top-notch honors students to major in the environmental sciences is a critical step to ensure that we have the human capital to tackle complicated environmental problems successfully. Planning and implementing an honors degree is no trivial task. Based upon a recently completed and implemented set of programmatic revisions*, this poster showcases a successful example of an honors curriculum in environmental science to recruit and educate dynamic thinkers capable of improving the quality of our environment. The interdisciplinary environmental science program at the University of Delaware emphasizes the cross-cutting among earth's spheres through a core set of courses which employ a quantitative approach which is supplemented by several environmental policy courses. The core is coupled with six different thematic concentrations (students choose one) which permit the student to delve into a particular area of environmental science. The honors component of the degree consists of twelve additional credits. These credits are met through a specially designed introductory environmental course, a field experience requiring data collection, analysis, and write-up, a capstone course, and one other environmentally related course. The environmental sciences honors curriculum outlined in this poster may serve as a useful guide to others wishing to establish an honors program of their own in environmental science to recruit and prepare the next generation to mitigate environmental degradation. -------------- * Please note that the planning process for the environmental programs was and is the collective effort of many dedicated people. Current members of the

  6. Ciência e Sustentabilidade: a contribuição da educação ambiental Science and Sustainability: the contribution of environmental education

    Directory of Open Access Journals (Sweden)

    Marcos Antonio do Santos Reigota

    2007-06-01

    Full Text Available No contexto político, científico e cultural da problemática ambiental, a educação ambiental tem uma história nos debates científicos e epistemológicos. A educação ambiental brasileira oferece sólidos elementos para mostrar que, apesar de todas as barreiras, outro tipo de ciência foi, está sendo feita e tende a consolidar-se. Com visões alternativas e paradigmas conseqüentes com a construção da sociedade sustentável orientada à democracia, justiça e ecologia. Sugere a análise da trajetória e a recepção dos pesquisadores para revelar o processo de constituição de conceitos (sustentabilidade e uma área de conhecimento (educação ambiental. Constata que a construção de uma sociedade sustentável é uma constante dúvida e utopia.In the political, scientific and cultural context of the environmental issue, environmental education has a history in the scientific and epistemological debates. Brazilian environmental education offers solid elements to prove that, in spite of all the difficulties, another type of science is being produced and tends to consolidate itself, with alternative views and consequent paradigms with the construction of a sustainable society oriented towards democracy, justice and ecology. The article suggests the analysis of the trajectory and the reception of the researchers to reveal the construction process of concepts (sustainability and a field of knowledge (environmental education. It concludes that the construction of a sustainable society is a constant doubt and utopia.

  7. Environmental education curriculum evaluation questionnaire: A reliability and validity study

    Science.gov (United States)

    Minner, Daphne Diane

    The intention of this research project was to bridge the gap between social science research and application to the environmental domain through the development of a theoretically derived instrument designed to give educators a template by which to evaluate environmental education curricula. The theoretical base for instrument development was provided by several developmental theories such as Piaget's theory of cognitive development, Developmental Systems Theory, Life-span Perspective, as well as curriculum research within the area of environmental education. This theoretical base fueled the generation of a list of components which were then translated into a questionnaire with specific questions relevant to the environmental education domain. The specific research question for this project is: Can a valid assessment instrument based largely on human development and education theory be developed that reliably discriminates high, moderate, and low quality in environmental education curricula? The types of analyses conducted to answer this question were interrater reliability (percent agreement, Cohen's Kappa coefficient, Pearson's Product-Moment correlation coefficient), test-retest reliability (percent agreement, correlation), and criterion-related validity (correlation). Face validity and content validity were also assessed through thorough reviews. Overall results indicate that 29% of the questions on the questionnaire demonstrated a high level of interrater reliability and 43% of the questions demonstrated a moderate level of interrater reliability. Seventy-one percent of the questions demonstrated a high test-retest reliability and 5% a moderate level. Fifty-five percent of the questions on the questionnaire were reliable (high or moderate) both across time and raters. Only eight questions (8%) did not show either interrater or test-retest reliability. The global overall rating of high, medium, or low quality was reliable across both coders and time, indicating

  8. Using Ionizing Radiation Detectors. Module 11. Vocational Education Training in Environmental Health Sciences.

    Science.gov (United States)

    Consumer Dynamics Inc., Rockville, MD.

    This module, one of 25 on vocational education training for careers in environmental health occupations, contains self-instructional materials on using ionizing radiation detectors. Following guidelines for students and instructors and an introduction that explains what the student will learn are three lessons: (1) naming and telling the function…

  9. Fermilab Friends for Science Education | About Us

    Science.gov (United States)

    Fermilab Friends for Science Education FFSE Home About Us Join Us Support Us Contact Us About Us national leader in precollege science education. From the first Summer Institute for Science Teachers held year over 37,000 students, and 2,500 teachers participated in programs through the Education Office

  10. Toward Fostering Environmental Political Participation: Framing an Agenda for Environmental Education Research

    Science.gov (United States)

    Levy, Brett L. M.; Zint, Michaela T.

    2013-01-01

    Scholars of environmental education (EE) and education for sustainable development (ESD) have been among the environmental leaders calling for individuals to become increasingly engaged in political action aimed at addressing environmental and sustainability issues. Few, however, have studied how educational experiences might foster greater…

  11. Partnership of Environmental Education and Research-A compilation of student research, 1999-2008

    Science.gov (United States)

    Bradley, Michael W.; Armstrong, Patrice; Byl, Thomas D.

    2011-01-01

    The U.S. Geological Survey (USGS) Tennessee Water Science Center and the College of Engineering and Technology at Tennessee State University developed a Partnership in Environmental Education and Research (PEER) to support environmental research at TSU and to expand the environmental research capabilities of the USGS in Tennessee. The PEER program is driven by the research needs to better define the occurrence, fate, and transport of contaminants in groundwater and surface water. Research in the PEER program has primarily focused on the transport and remediation of organic contamination in karst settings. Research conducted through the program has also expanded to a variety of media and settings. Research areas include contaminant occurrence and transport, natural and enhanced bioremediation, geochemical conditions in karst aquifers, mathematical modeling for contaminant transport and degradation, new methods to evaluate groundwater contamination, the resuspension of bacteria from sediment in streams, the use of bioluminescence and chemiluminescence to identify the presence of contaminants, and contaminant remediation in wetlands. The PEER program has increased research and education opportunities for students in the College of Engineering, Technology, and Computer Science and has provided students with experience in presenting the results of their research. Students in the program have participated in state, regional, national and international conferences with more than 140 presentations since 1998 and more than 40 student awards. The PEER program also supports TSU outreach activities and efforts to increase minority participation in environmental and earth science programs at the undergraduate and graduate levels. TSU students and USGS staff participate in the TSU summer programs for elementary and high school students to promote earth sciences. The 2007 summer camps included more than 130 students from 20 different States and Washington DC.

  12. CEO Education and Corporate Environmental Footprint

    DEFF Research Database (Denmark)

    Amore, Mario Daniele; Bennedsen, Morten; Larsen, Birthe

    We analyze the effect of CEO education on environmental decision-making. Using a unique sample of Danish firms from 1996 to 2012, we find that CEO education significantly improves firms’ energy efficiency. We derive causality using health shocks: the hospitalization of highly educated CEOs induces...... a drop in energy efficiency, whereas the hospitalization of less educated CEOs does not have any significant effect. Exploring the mechanisms at play, we show that our results are driven by the length rather than the field of education. CEO education improves corporate energy efficiency through personal...... environmental awareness: highly educated CEOs exhibit greater concerns for climate change, as measured by a survey of social preferences, and drive more environmentally-efficient cars. Taken together, our findings suggest that education shapes managerial styles giving rise to greater sustainability in corporate...

  13. Preparing Future Secondary Computer Science Educators

    Science.gov (United States)

    Ajwa, Iyad

    2007-01-01

    Although nearly every college offers a major in computer science, many computer science teachers at the secondary level have received little formal training. This paper presents details of a project that could make a significant contribution to national efforts to improve computer science education by combining teacher education and professional…

  14. Emphasizing Morals, Values, Ethics, and Character Education in Science Education and Science Teaching

    Science.gov (United States)

    Chowdhury, Mohammad

    2016-01-01

    This article presents the rationale and arguments for the presence of morals, values, ethics and character education in science curriculum and science teaching. The author examines how rapid science and technological advancements and globalization are contributing to the complexities of social life and underpinning the importance of morals, values…

  15. Building a Global Ocean Science Education Network

    Science.gov (United States)

    Scowcroft, G. A.; Tuddenham, P. T.; Pizziconi, R.

    2016-02-01

    It is imperative for ocean science education to be closely linked to ocean science research. This is especially important for research that addresses global concerns that cross national boundaries, including climate related issues. The results of research on these critical topics must find its way to the public, educators, and students of all ages around the globe. To facilitate this, opportunities are needed for ocean scientists and educators to convene and identify priorities and strategies for ocean science education. On June 26 and 27, 2015 the first Global Ocean Science Education (GOSE) Workshop was convened in the United States at the University of Rhode Island Graduate School of Oceanography. The workshop, sponsored by the Consortium for Ocean Science Exploration and Engagement (COSEE) and the College of Exploration, had over 75 participants representing 15 nations. The workshop addressed critical global ocean science topics, current ocean science research and education priorities, advanced communication technologies, and leveraging international ocean research technologies. In addition, panels discussed elementary, secondary, undergraduate, graduate, and public education across the ocean basins with emphasis on opportunities for international collaboration. Special presentation topics included advancements in tropical cyclone forecasting, collaborations among Pacific Islands, ocean science for coastal resiliency, and trans-Atlantic collaboration. This presentation will focus on workshop outcomes as well as activities for growing a global ocean science education network. A summary of the workshop report will also be provided. The dates and location for the 2016 GOES Workshop will be announced. See http://www.coexploration.net/gose/index.html

  16. Artificial Intelligence and Science Education.

    Science.gov (United States)

    Good, Ron

    1987-01-01

    Defines artificial intelligence (AI) in relation to intelligent computer-assisted instruction (ICAI) and science education. Provides a brief background of AI work, examples of expert systems, examples of ICAI work, and addresses problems facing AI workers that have implications for science education. Proposes a revised model of the Karplus/Renner…

  17. Environmental Education Policy Development in Zimbabwe: An ...

    African Journals Online (AJOL)

    National environmental education policy is essential for guiding and coordinating environmental education activities within a country. The Zimbabwean Environmental Education Policy development process took place between 2000 and 2001.This paper looks at stages in the policy development process, the factors that ...

  18. Leadership, Responsibility, and Reform in Science Education.

    Science.gov (United States)

    Bybee, Rodger W.

    1993-01-01

    Regards leadership as central to the success of the reform movement in science education. Defines leadership and introduces a model of leadership modified from the one developed by Edwin Locke and his associates. Provides an overview of the essential qualities of leadership occurring in science education. Discusses reforming science education and…

  19. Ecotourism and Environmental Education: Relationships.

    Science.gov (United States)

    Eagles, Paul F. J.

    1999-01-01

    Examines relationships among environmental education, ecotourism, and public attitudes toward conservation. The global ecotourism industry and the worldwide growth of national parks and other protected areas reflect the long-term impact of environmental education. The entire cycle of protection, ecotourism use of protected areas, and more positive…

  20. Data Mining Tools in Science Education

    OpenAIRE

    Premysl Zaskodny

    2012-01-01

    The main principle of paper is Data Mining in Science Education (DMSE) as Problem Solving. The main goal of paper is consisting in Delimitation of Complex Data Mining Tool and Partial Data Mining Tool of DMSE. The procedure of paper is consisting of Data Preprocessing in Science Education, Data Processing in Science Education, Description of Curricular Process as Complex Data Mining Tool (CP-DMSE), Description of Analytical Synthetic Modeling as Partial Data Mining Tool (ASM-DMSE) and finally...

  1. Perspectives of women of color in science-based education and careers. Summary of the conference on diversity in science

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    1998-12-01

    Research on inequality or stratification in science and engineering tends to concentrate on black/white or male/female difference; very few studies have discussions of both race and gender. Consequently, very little is known about the exact course that women of color take in science-based education and employment or about the course that steers them out of science-based careers. Questions abound: What are the environmental factors that affect the choices in education and science-based careers of women of color? What has influenced women of color who currently are in science-based careers? Is critical mass important and, if so, what are the keys to increasing it? What recommendations can be made to colleges and universities, faculty members, employers, the federal government, women of color themselves, and to improve the conditions and numbers of women of color in science-based careers? These questions prompted the National Research Council`s Committee on Women in Science and Engineering (CWSE) to convene a conference on Diversity in Science: Perspectives on the Retention of Minority Women in Science, Engineering, and Health-Care Professions, held on October 21--23, 1995. Confronting the problem of the lack of knowledge about the journey of women of color in science-based education and career, the conference offered opportunities for these women to describe the paths that they have taken and to identify strategies for success. Their perspectives ground this report. For purposes of this document, women of color include women in the following racial or ethnic groups: Hispanics, African-Americans, Asian and Pacific Islanders, and American Indians and Alaskan Natives. Science-based careers include those in the physical sciences and mathematics, life sciences, social sciences, and engineering.

  2. Science Identity in Informal Education

    Science.gov (United States)

    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

  3. Status and developmental strategy of nuclear agricultural sciences in researches of eco-environmental sciences in agriculture

    International Nuclear Information System (INIS)

    Hua Luo; Wang Xunqing

    2001-01-01

    The concept, research scopes, research progress and achievement of nuclear agricultural sciences in past several decades in China, as well as the relationship between nuclear agriculture research and eco-environmental sciences were described. The disciplinary frontier, major research fields and priority developmental fields of nuclear agriculture in eco-environmental sciences was displayed. Suggestions were made to improve and strengthen nuclear agriculture research. Those provided basic source materials and consideration for application developmental strategy of nuclear agriculture in eco-environmental sciences

  4. The effectiveness of environmental education programs from the perspectives of three stakeholders: Participants, sponsors, and professionals

    Science.gov (United States)

    Luera, Gail Rose

    As the field of environmental education has matured since its inception in 1970, so have the number and variety of environmental programs. Along with the increased number of programs has come a need for in-depth program evaluations. This is especially critical because of reductions in educational funding and competition for a place in an already crowded curriculum. Evaluation is essential to convince the educational community that environmental education can improve the curriculum, ensure cost effectiveness, and become more relevant to students. Drawing on program evaluation research, action research, and interpretive (qualitative) research to strengthen the research design and methodology, this dissertation explores how different stakeholders of two environmental education programs determine program effectiveness. Effectiveness was investigated primarily through the use of in-depth interviews of participants, program sponsors, and professionals. Program success at the professional field level was determined by criteria set by the North American Association for Environmental Education. Characteristics considered in the selection of programs for this study included: method of dissemination, sponsor, subject focus, the method of action which they encourage, and their vision for the future. Using the qualitative case study approach, the Orange County Outdoor Science School in California and Project WILD in Michigan were evaluated. The results show that all levels of stakeholders perceived the two programs to be effective. Areas of effectiveness varied with each program and by stakeholder level. Issues facing each program also differed. At the Orange County Outdoor Science School, program cost was named as the major issue. The most often cited issues for Project WILD was public awareness of the program and stabilizing long term financial support for the Michigan program. Interview data were analyzed at the question level in addition to the thematic level. Themes which

  5. How do marine and coastal citizen science experiences foster environmental engagement?

    Science.gov (United States)

    Dean, Angela J; Church, Emma K; Loder, Jenn; Fielding, Kelly S; Wilson, Kerrie A

    2018-05-01

    Citizen science programs enable community involvement in scientific research. In addition to fostering greater science literacy, some citizen science programs aim to foster engagement in environmental issues. However, few data are available to indicate whether and how citizen science programs can achieve greater environmental engagement. We survey individuals choosing to attend one of seventeen reef citizen science events and examine the extent to which attendees reported three indicators of greater environmental engagement: (i) willingness to share information, (ii) increased support for marine conservation and citizen science, and (iii) intentions to adopt a new behavior. Most participants reported being willing to share information about reef conservation (91%) and described increased support for marine science and conservation (87%). Half of participants (51%) reported intentions to adopt a new conservation behavior. We found that key elements of the citizen science experience associated with these outcomes were learning about actions to protect reefs and coasts (procedural learning), experiencing surprise, and experiencing negative emotions about environmental problems. Excitement was also associated with positive outcomes, but only in participants who were less likely to see themselves as environmental, or were less frequent visitors to reefs and coasts. Importantly, the association between factual learning and environmental engagement outcomes was limited or negative. These findings suggest that the way citizen science experiences make people feel, may be more important for fostering future environmental engagement than factual-based learning. When designing citizen science programs for community members, these findings provide a reminder to not focus on provision of factual information alone, but to highlight environmental impacts while providing meaningful experiences and building environmental skills. Copyright © 2018 Elsevier Ltd. All rights reserved.

  6. Fermilab Friends for Science Education | Contact Us

    Science.gov (United States)

    Fermilab Friends for Science Education FFSE Home About Us Join Us Support Us Contact Us Contact Us Science Education P.O Box 500, MS 777 Batavia, IL 60510-5011 (630) 840-3094 * fax: (630) 840-2500 E-mail : Membership Send all other communications to: Susan Dahl, President Fermilab Friends for Science Education Box

  7. ENVIRONMENTAL SYSTEMS MANAGEMENT: TOWARDS A NEW SCIENCE OF SUSTAINABLE ENVIRONMENTAL MANAGEMENT

    Science.gov (United States)

    Environmental Systems Management (ESM) is the management of environmental problems at the systems level fully accounting for the multi-dimensional nature of the environment. This includes socio-economic dimensions as well as the usual physical and life science aspects of environm...

  8. Environmental education policy research

    DEFF Research Database (Denmark)

    Læssøe, Jeppe; Feinstein, Noah Weeth; Blum, Nicole

    2013-01-01

    in the areas of Environmental Education (EE), Education for Sustainable Development and Climate Change Education. It especially makes a case for two kinds of research on EE policy: (1) a multi-sited approach to empirical documentation and theory development which explores the relationships between...

  9. A System Approach to Environmental Education

    Directory of Open Access Journals (Sweden)

    Z. Kostova

    2007-09-01

    Full Text Available A system approach to environmental education (EE is developed. By making use of it the educators will be able to introduce successfully ecological principles and global environmental problems in the educational system for the development of environmental culture, consciousness and behavior. It embraces a long period of thinking, designing, experimenting and rethinking in the light of the new ideas, concerning humanity-nature relationships. The core of the system approach is represented by environmental consciousness, which is the driving force of environmentally responsible behavior. The system approach is concerned with constructing an innovative model of EE, which consists of three elements: didactical, conceptual and technological and six integrating concepts, uniting the studies of the different school subjects under the global movement for sustainable development. EE is regarded to be an essential part of the education for sustainable development (ESD.

  10. Oak Ridge Institute for Science and Education, Medical Sciences Division report for 1994

    Energy Technology Data Exchange (ETDEWEB)

    Snyder, F.; Poston, S.; Engle, J. [eds.

    1995-08-01

    The primary mission of the Medical Sciences Division is (1) to conduct basic and applied biomedical research on human health related to energy systems, (2) to provide technical assistance and training in occupational and environmental medicine, and (3) to make related biomedical applications available to others through technology transfer. As can be gleaned from this report, the strengths and capabilities of their staff in carrying out this mission are closely aligned with the four core competencies of ORISE: (1) occupational and environmental health, (2) environmental and safety evaluation and analysis, (3) education and training, and (4) enabling research. Brief descriptions of the various scientific and technical programs and their progress, as well as the staff responsible for the accomplishments made during 1994, are presented in this report. Research programs include the following: biochemistry; cytogenetics; Center for Epidemiologic Research; Center for Human Reliability Studies; occupational medicine; Radiation Emergency Assistance Center/Training Site; and Radiation Internal Dose Information Center.

  11. Oak Ridge Institute for Science and Education, Medical Sciences Division report for 1994

    International Nuclear Information System (INIS)

    Snyder, F.; Poston, S.; Engle, J.

    1995-01-01

    The primary mission of the Medical Sciences Division is (1) to conduct basic and applied biomedical research on human health related to energy systems, (2) to provide technical assistance and training in occupational and environmental medicine, and (3) to make related biomedical applications available to others through technology transfer. As can be gleaned from this report, the strengths and capabilities of their staff in carrying out this mission are closely aligned with the four core competencies of ORISE: (1) occupational and environmental health, (2) environmental and safety evaluation and analysis, (3) education and training, and (4) enabling research. Brief descriptions of the various scientific and technical programs and their progress, as well as the staff responsible for the accomplishments made during 1994, are presented in this report. Research programs include the following: biochemistry; cytogenetics; Center for Epidemiologic Research; Center for Human Reliability Studies; occupational medicine; Radiation Emergency Assistance Center/Training Site; and Radiation Internal Dose Information Center

  12. Science initial teacher education and superdiversity: educating science teachers for a multi-religious and globalised science classroom

    Science.gov (United States)

    De Carvalho, Roussel

    2016-06-01

    Steven Vertovec (2006, 2007) has recently offered a re-interpretation of population diversity in large urban centres due to a considerable increase in immigration patterns in the UK. This complex scenario called superdiversity has been conceptualised to help illuminate significant interactions of variables such as religion, language, gender, age, nationality, labour market and population distribution on a larger scale. The interrelationships of these themes have fundamental implications in a variety of community environments, but especially within our schools. Today, London schools have over 300 languages being spoken by students, all of whom have diverse backgrounds, bringing with them a wealth of experience and, most critically, their own set of religious beliefs. At the same time, Science is a compulsory subject in England's national curriculum, where it requires teachers to deal with important scientific frameworks about the world; teaching about the origins of the universe, life on Earth, human evolution and other topics, which are often in conflict with students' religious views. In order to cope with this dynamic and thought-provoking environment, science initial teacher education (SITE)—especially those catering large urban centres—must evolve to equip science teachers with a meaningful understanding of how to handle a superdiverse science classroom, taking the discourse of inclusion beyond its formal boundaries. Thus, this original position paper addresses how the role of SITE may be re-conceptualised and re-framed in light of the immense challenges of superdiversity as well as how science teachers, as enactors of the science curriculum, must adapt to cater to these changes. This is also the first in a series of papers emerging from an empirical research project trying to capture science teacher educators' own views on religio-scientific issues and their positions on the place of these issues within science teacher education and the science classroom.

  13. Animals in Environmental Education Research

    Science.gov (United States)

    Spannring, Reingard

    2017-01-01

    Over the past few decades, the increase in public and scholarly attention to human-animal relations has inspired an animal turn in a number of academic disciplines including environmental education research. This paper reviews the literature on animals in environmental education with respect to its theoretical foundations in critical pedagogy,…

  14. Beyond the Limitations of Environmental Education in Japan

    Science.gov (United States)

    Imamura, Mitsuyuki

    2017-01-01

    Environmental education has not spread as widely in Japan as expected and therefore has not had any significant impact on environmental problems, even though many educators and researchers have devoted themselves to environmental educational practice. Why is environmental education not popular in Japan, and what does this tell us? The purpose of…

  15. [Environmental Hazards Assessment Program annual report, June 1992--June 1993]. Needs assessment for the proposed masters degree program in environmental science at the Medical University of South Carolina: EHAP Volume 1, No. 2

    Energy Technology Data Exchange (ETDEWEB)

    Hoomani, J.

    1993-05-01

    There will be a critical shortage of professionals who are educated to deal with environmental problems by 1997. This was the major finding of a 1992 study conducted by the Oak Ridge Associated Universities, Incorporated and the Pacific Northwest Laboratory (Publication Number PAL-8171, CU-700). The study was done to determine the manpower needs of the Office of Environmental Restoration and Waste Management in the US Department of Energy (DOE). Although the focus of the study was the 19 sites of the DOE complex, including the Savannah River Site in South Carolina, the study documented that such shortages will affect other major agencies and organizations including the US Department of Interior, the US Department of Defense, the Environmental Protection Agency, state and local governmental agencies, private agencies, and manufacturing enterprises throughout the State of South Carolina and the National. The Oak Ridge Study also documented that a variety of professional positions requiring environmental expertise are difficult to fill because traditional educational programs in physical science, engineering, health science, public policy, and administration have not adequately responded to the unique nature of these emerging specialities. This lack of educational preparation has necessitated extensive on-site training of new employees before they can become productive members of the environmental work force. Unique educational initiatives such as the Environmental Studies program proposed here are vital to address the long-term demand for environmental professionals.

  16. Science and Technology Education in the STES Context in Primary Schools: What Should It Take?

    Science.gov (United States)

    Zoller, Uri

    2011-10-01

    Striving for sustainability requires a paradigm shift in conceptualization, thinking, research and education, particularly concerning the science-technology-environment-society (STES) interfaces. Consequently, `STES literacy' requires the development of students' question asking, critical, evaluative system thinking, decision making and problem solving capabilities, in this context, via innovative implementable higher-order cognitive skills (HOCS)-promoting teaching, assessment and learning strategies. The corresponding paradigms shift in science and technology education, such as from algorithmic teaching to HOCS-promoting learning is unavoidable, since it reflects the social pressure, worldwide, towards more accountable socially- and environmentally-responsible sustainable development. Since most of the STES- and, recently STEM (science-technology-engineering-mathematics)-related research in science education has been focused on secondary and tertiary education, it is vital to demonstrate the relevance of this multifaceted research to the science and technology teaching in primary schools. Our longitudinal STES education-related research and curriculum development point to the very little contribution, if any, of the traditional science teaching to "know", to the development of students' HOCS capabilities. On the other hand, there appears to be a `general agreement', that the contemporary dominant lower-order cognitive skills (LOCS) teaching and assessment strategies applied in science and technology education are, in fact, restraining the natural curiosity and creativity of primary school (and younger?) pupils/children. Since creative thinking as well as evaluative system thinking, decision making, problem solving and … transfer constitute an integral part of the HOCS conceptual framework, the appropriateness of "HOCS promoting" teaching, and the relevance of science and technology, to elementary education in the STES context, is apparent. Therefore, our

  17. Augmented Reality in Science Education

    DEFF Research Database (Denmark)

    Nielsen, Birgitte Lund; Brandt, Harald; Swensen, Hakon

    Augmented reality (AR) holds great promise as a learning tool. However, most extant studies in this field have focused on the technology itself. The poster presents findings from the first stage of the AR-sci project addressing the issue of applying AR for educational purposes. Benefits and chall......Augmented reality (AR) holds great promise as a learning tool. However, most extant studies in this field have focused on the technology itself. The poster presents findings from the first stage of the AR-sci project addressing the issue of applying AR for educational purposes. Benefits...... and challenges related to AR enhancing student learning in science in lower secondary school were identified by expert science teachers, ICT designers and science education researchers from four countries in a Delphi survey. Findings were condensed in a framework to categorize educational AR designs....

  18. General Atomics Sciences Education Foundation Outreach Programs

    Science.gov (United States)

    Winter, Patricia S.

    1997-11-01

    Scientific literacy for all students is a national goal. The General Atomics (GA) Foundation Outreach Program is committed to playing a major role in enhancing pre-college education in science, engineering and new technologies. GA has received wide recognition for its Sciences Education Program, a volunteer effort of GA employees and San Diego science teachers. GA teacher/scientist teams have developed inquiry-based education modules and associated workshops based on areas of core competency at GA: Fusion -- Energy of the Stars; Explorations in Materials Science; Portrait of an Atom; DNA Technology. [http://www.sci-ed-ga.org]. Workshops [teachers receive printed materials and laboratory kits for ``hands-on" modules] have been presented for 700+ teachers from 200+ area schools. Additional workshops include: University of Denver for Denver Public Schools; National Educators Workshop; Standard Experiments in Engineering Materials; Update '96 in Los Alamos; Newspapers in Education Workshop (LA Times); American Chemical Society Regional/National meetings, and California Science Teachers Association Conference. Other outreach includes High School Science Day, school partnerships, teacher and student mentoring and the San Diego Science Alliance [http://www.sdsa.org].

  19. Symposium 3 - Science Education “Leopoldo de Meis”: The Critical Importance of Science Education for Society

    Directory of Open Access Journals (Sweden)

    Bruce Albert

    2015-08-01

    Full Text Available Symposium 3 - Science Education “Leopoldo de Meis” Chair: Wagner Seixas da Silva, Universidade Federal do Rio de JaneiroAbstract:Three ambitious goals for science education:1. Enable all children to acquire the problem-solving, thinking, and communication skills of scientists – so that they can be productive and competitive in the new world economy.2. Generate a “scientific temper” for each nation, with scientifically trained people in many professions, ensuring the rationality and the tolerance essential for a democratic society.3. Help each nation generate new scientific knowledge and technology by casting the widest possible net for talent.My preferred strategy for the United States:1. Science education should have a much larger role in all school systems, but only if this science education is of a different kind than is experienced in most schools today.2. Making such a change will require a redefinition of what we mean by the term  “science education”.3. To create continually improving education systems, we will need much more collaborative, effective, and use-inspired education research - research that is focused on real school needs and that integrates the best school teachers into the work.4. Our best teachers need to have a much larger voice in helping to steer our national and state policies, as well as in our local school systems!

  20. Trends of Science Education Research: An Automatic Content Analysis

    Science.gov (United States)

    Chang, Yueh-Hsia; Chang, Chun-Yen; Tseng, Yuen-Hsien

    2010-01-01

    This study used scientometric methods to conduct an automatic content analysis on the development trends of science education research from the published articles in the four journals of "International Journal of Science Education, Journal of Research in Science Teaching, Research in Science Education, and Science Education" from 1990 to 2007. The…

  1. 76 FR 67748 - National Institute of Environmental Health Sciences; Notice of Meeting

    Science.gov (United States)

    2011-11-02

    ... Environmental Health Sciences; Notice of Meeting Pursuant to section 10(a) of the Federal Advisory Committee Act...., Director, Division of Extramural Research and Training, Nat. Inst. of Environmental Health Sciences... Manpower Development in the Environmental Health Sciences; 93.113, Biological Response to Environmental...

  2. An Evaluation of the Science Education Component of the Cross River State Science and Technical Education Project

    Science.gov (United States)

    Ekuri, Emmanuel Etta

    2012-01-01

    The Cross River State Science and Technical Education Project was introduced in 1992 by edict number 9 of 20 December 1991, "Cross River State Science and Technical Education Board Edit, 20 December, 1991", with the aim of improving the quality of science teaching and learning in the state. As the success of the project depends…

  3. Constructivism in Science and Science Education: A Philosophical Critique

    Science.gov (United States)

    Nola, Robert

    This paper argues that constructivist science education works with an unsatisfactory account of knowledge which affects both its account of the nature of science and of science education. The paper begins with a brief survey of realism and anti-realism in science and the varieties of constructivism that can be found. In the second section the important conception of knowledge and teaching that Plato develops in the Meno is contrasted with constructivism. The section ends with an account of the contribution that Vico (as understood by constructivists), Kant and Piaget have made to constructivist doctrines. Section three is devoted to a critique of the theory of knowledge and the anti-realism of von Glaserfeld. The final section considers the connection, or lack of it, between the constructivist view of science and knowledge and the teaching of science.

  4. Publications in biomedical and environmental sciences programs, 1980

    Energy Technology Data Exchange (ETDEWEB)

    Pfuderer, H.A.; Moody, J.B.

    1981-07-01

    This bibliography contains 690 references to articles in journals, books, and reports published in the subject area of biomedical and environmental sciences during 1980. There are 529 references to articles published in journals and books and 161 references to reports. Staff members in the Biomedical and Environmental Sciences divisions have other publications not included in this bibliography; for example, theses, book reviews, abstracts published in journals or symposia proceedings, pending journal publications and reports such as monthly and bimonthly progress reports, contractor reports, and reports for internal distribution. This document is sorted by the division, and then alphabetically by author. The sorting by divisions separates the references by subject area in a simple way. The divisions represented in the order that they appear in the bibliography are Analytical Chemistry, Biology, Chemical Technology, Information R and D, Health and Safety Research, Energy, Environmental Sciences, and Computer Sciences.

  5. Publications in biomedical and environmental sciences programs, 1980

    International Nuclear Information System (INIS)

    Pfuderer, H.A.; Moody, J.B.

    1981-07-01

    This bibliography contains 690 references to articles in journals, books, and reports published in the subject area of biomedical and environmental sciences during 1980. There are 529 references to articles published in journals and books and 161 references to reports. Staff members in the Biomedical and Environmental Sciences divisions have other publications not included in this bibliography; for example, theses, book reviews, abstracts published in journals or symposia proceedings, pending journal publications and reports such as monthly and bimonthly progress reports, contractor reports, and reports for internal distribution. This document is sorted by the division, and then alphabetically by author. The sorting by divisions separates the references by subject area in a simple way. The divisions represented in the order that they appear in the bibliography are Analytical Chemistry, Biology, Chemical Technology, Information R and D, Health and Safety Research, Energy, Environmental Sciences, and Computer Sciences

  6. Bioremediation Education Science and Technology (BEST) Program Annual Report 1999; TOPICAL

    International Nuclear Information System (INIS)

    Hazen, Terry C.

    2000-01-01

    The Bioremediation, Education, Science and Technology (BEST) partnership provides a sustainable and contemporary approach to developing new bioremedial technologies for US Department of Defense (DoD) priority contaminants while increasing the representation of underrepresented minorities and women in an exciting new biotechnical field. This comprehensive and innovative bioremediation education program provides under-represented groups with a cross-disciplinary bioremediation cirruculum and financial support, coupled with relevant training experiences at advanced research laboratories and field sites. These programs are designed to provide a stream of highly trained minority and women professionals to meet national environmental needs

  7. A Mentoring Program in Environmental Science for Underrepresented Groups

    Science.gov (United States)

    Stevens, L.; Rizzo, D. M.

    2009-12-01

    We developed a four-year program, combining educational and career support and research activities, to recruit and retain students from underrepresented groups in environmental sciences. Specifically, the program: ○ Assigns each student a faculty or graduate student mentor with whom the student conducts research activities. ○ Includes a weekly group meeting for team building and to review professional development and academic topics, such as time management and research ethics. ○ Requires students to make multiple formal presentations of their research proposals and results. ○ Provides scholarships and stipends for both the academic year and to engage students in summer research. The program seeks to achieve several goals including: ● Enhance academic performance. ● Encourage continued study in environmental science. ● Facilitate students completing their studies at UVM. ● Increase students’ interest in pursuing science careers. ● Create a more welcoming academic environment. To assess progress toward achievement of these goals, we conducted individual structured interviews with participating undergraduate students, graduate students, and faculty members at two points in time. First, interviews were conducted in the fall of 2007 after two years, and again in spring 2009, after four years. An independent research consultant, Dr. Livingston, conducted the interviews. In 2009, over the course of three days, the interviews included three graduate student and two faculty mentors, and six of the seven undergraduate students. Of the six students, three were juniors and three were graduating seniors. Results of the 2009 interviews echoed those of 2007. Both students and their mentors are quite satisfied with the program. The student presentations, weekly meetings, mentoring relationships, and summer research experiences all get high ratings from program participants. Students give high praise to their mentors and the program directors for providing

  8. Science in General Education

    Science.gov (United States)

    Read, Andrew F.

    2013-01-01

    General education must develop in students an appreciation of the power of science, how it works, why it is an effective knowledge generation tool, and what it can deliver. Knowing what science has discovered is desirable but less important.

  9. Reforming Science Education: Part I. The Search for a Philosophy of Science Education

    Science.gov (United States)

    Schulz, Roland M.

    2009-04-01

    The call for reforms in science education has been ongoing for a century, with new movements and approaches continuously reshaping the identity and values of the discipline. The HPS movement has an equally long history and taken part in the debates defining its purpose and revising curriculum. Its limited success, however, is due not only to competition with alternative visions and paradigms (e.g. STS, multi-culturalism, constructivism, traditionalism) which deadlock implementation, and which have led to conflicting meanings of scientific literacy, but the inability to rise above the debate. At issue is a fundamental problem plaguing science education at the school level, one it shares with education in general. It is my contention that it requires a guiding “metatheory” of education that can appropriately distance itself from the dual dependencies of metatheories in psychology and the demands of socialization—especially as articulated in most common conceptions of scientific literacy tied to citizenship. I offer as a suggestion Egan’s cultural-linguistic theory as a metatheory to help resolve the impasse. I hope to make reformers familiar with his important ideas in general and more specifically, to show how they can complement HPS rationales and reinforce the work of those researchers who have emphasized the value of narrative in learning science. This will be elaborated in Part II of a supplemental paper to the present one. As a prerequisite to presenting Egan’s metatheory I first raise the issue of the need for a conceptual shift back to philosophy of education within the discipline, and thereto, on developing and demarcating true educational theories (essentially neglected since Hirst). In the same vein it is suggested a new research field should be opened with the express purpose of developing a discipline-specific “philosophy of science education” (largely neglected since Dewey) which could in addition serve to reinforce science education

  10. Reconceptualizing Environmental Education: Taking Account of Reality.

    Science.gov (United States)

    Dillon, Justin; Teamey, Kelly

    2002-01-01

    Investigates the pros and cons of integrating environmental education into the school curriculum. Focusing solely on environmental education's role in the school curriculum ignores a range of factors that affect its efficacy in the majority of the world. Suggests a conceptualization of environmental education that takes into account a range of…

  11. What Is "Agency"? Perspectives in Science Education Research

    Science.gov (United States)

    Arnold, Jenny; Clarke, David John

    2014-01-01

    The contemporary interest in researching student agency in science education reflects concerns about the relevance of schooling and a shift in science education towards understanding learning in science as a complex social activity. The purpose of this article is to identify problems confronting the science education community in the development…

  12. How science makes environmental controversies worse

    International Nuclear Information System (INIS)

    Sarewitz, Daniel

    2004-01-01

    I use the example of the 2000 US Presidential election to show that political controversies with technical underpinnings are not resolved by technical means. Then, drawing from examples such as climate change, genetically modified foods, and nuclear waste disposal, I explore the idea that scientific inquiry is inherently and unavoidably subject to becoming politicized in environmental controversies. I discuss three reasons for this. First, science supplies contesting parties with their own bodies of relevant, legitimated facts about nature, chosen in part because they help make sense of, and are made sensible by, particular interests and normative frameworks. Second, competing disciplinary approaches to understanding the scientific bases of an environmental controversy may be causally tied to competing value-based political or ethical positions. The necessity of looking at nature through a variety of disciplinary lenses brings with it a variety of normative lenses, as well. Third, it follows from the foregoing that scientific uncertainty, which so often occupies a central place in environmental controversies, can be understood not as a lack of scientific understanding but as the lack of coherence among competing scientific understandings, amplified by the various political, cultural, and institutional contexts within which science is carried out. In light of these observations, I briefly explore the problem of why some types of political controversies become 'scientized' and others do not, and conclude that the value bases of disputes underlying environmental controversies must be fully articulated and adjudicated through political means before science can play an effective role in resolving environmental problems

  13. Environmental Sustainability and Quality Education: Perspectives ...

    African Journals Online (AJOL)

    Environmental Sustainability and Quality Education: Perspectives from a community living in a context of poverty. ... Southern African Journal of Environmental Education. Journal Home · ABOUT THIS ... AJOL African Journals Online. HOW TO ...

  14. The Impact of a Science Education Game on Students' Learning and Perception of Inhalants as Body Pollutants

    Science.gov (United States)

    Klisch, Yvonne; Miller, Leslie M.; Wang, Shu; Epstein, Joel

    2012-01-01

    This study investigated the knowledge gains and attitude shifts attributable to a unique online science education game, "Uncommon Scents." The game was developed to teach middle school students about the biological consequences of exposure to toxic chemicals in an environmental science context, as well as the risks associated with abusing these…

  15. Molecular Environmental Science and Synchrotron Radiation Facilities An Update of the 1995 DOE-Airlie Report on Molecular Environmental Science

    Energy Technology Data Exchange (ETDEWEB)

    Bargar, John R

    1999-05-07

    This workshop was requested by Dr. Robert Marianelli, Director of the DOE-BES Chemical Sciences Division, to update the findings of the Workshop on Molecular Environmental Sciences (MES) held at Airlie, VA, in July 1995. The Airlie Workshop Report defined the new interdisciplinary field referred to as Molecular Environmental Science (MES), reviewed the synchrotron radiation methods used in MES research, assessed the adequacy of synchrotron radiation facilities for research in this field, and summarized the beam time requirements of MES users based on a national MES user survey. The objectives of MES research are to provide information on the chemical and physical forms (speciation), spatial distribution, and reactivity of contaminants in natural materials and man-made waste forms, and to develop a fundamental understanding of the complex molecular-scale environmental processes, both chemical and biological, that affect the stability, transformations, mobility, and toxicity of contaminant species. These objectives require parallel studies of ''real'' environmental samples, which are complicated multi-phase mixtures with chemical and physical heterogeneities, and of simplified model systems in which variables can be controlled and fundamental processes can be examined. Only by this combination of approaches can a basic understanding of environmental processes at the molecular-scale be achieved.

  16. Molecular Environmental Science and Synchrotron Radiation Facilities An Update of the 1995 DOE-Airlie Report on Molecular Environmental Science

    International Nuclear Information System (INIS)

    Bargar, John R

    1999-01-01

    This workshop was requested by Dr. Robert Marianelli, Director of the DOE-BES Chemical Sciences Division, to update the findings of the Workshop on Molecular Environmental Sciences (MES) held at Airlie, VA, in July 1995. The Airlie Workshop Report defined the new interdisciplinary field referred to as Molecular Environmental Science (MES), reviewed the synchrotron radiation methods used in MES research, assessed the adequacy of synchrotron radiation facilities for research in this field, and summarized the beam time requirements of MES users based on a national MES user survey. The objectives of MES research are to provide information on the chemical and physical forms (speciation), spatial distribution, and reactivity of contaminants in natural materials and man-made waste forms, and to develop a fundamental understanding of the complex molecular-scale environmental processes, both chemical and biological, that affect the stability, transformations, mobility, and toxicity of contaminant species. These objectives require parallel studies of ''real'' environmental samples, which are complicated multi-phase mixtures with chemical and physical heterogeneities, and of simplified model systems in which variables can be controlled and fundamental processes can be examined. Only by this combination of approaches can a basic understanding of environmental processes at the molecular-scale be achieved

  17. [Re]considering queer theories and science education

    Science.gov (United States)

    Fifield, Steve; Letts, Will

    2014-06-01

    We take Mattias Lundin's Inviting queer ideas into the science classroom: studying sexual education from a queer perspective as a point of departure to explore some enduring issues related to the use of queer theories to interrogate science education and its practices. We consider the uneasy, polygamous relationship between gay and lesbian studies and queer theories; the border surveillance that characterizes so much of science [education]; the alluring call of binaries and binary thinking; the `all' within the catchcry `science for all'; and the need to better engage the fullness of science and the curriculum, in addition to noting silences around diverse sexes, sexualities, and desires. We catalogue some of the challenges that persist in this work, and offer thoughts about how to work with and against them to enact a more just and compelling science education.

  18. Understanding leadership in the environmental sciences

    OpenAIRE

    Evans, L.; Hicks, C.; Cohen, P.; Case, P.; Prideaux, M.; Mills, D.

    2015-01-01

    Leadership is often assumed, intuitively, to be an important driver of sustainable development. To understand how leadership is conceptualised and analysed in the environmental sciences and to discover what this research says about leadership outcomes, we conducted a review of environmental leadership research over the last ten years. We find that much of the environmental leadership literature we reviewed focuses on a few key individuals and desirable leadership competencies. It also reports...

  19. Space Life Sciences Research and Education Program

    Science.gov (United States)

    Coats, Alfred C.

    2001-01-01

    Since 1969, the Universities Space Research Association (USRA), a private, nonprofit corporation, has worked closely with the National Aeronautics and Space Administration (NASA) to advance space science and technology and to promote education in those areas. USRA's Division of Space Life Sciences (DSLS) has been NASA's life sciences research partner for the past 18 years. For the last six years, our Cooperative Agreement NCC9-41 for the 'Space Life Sciences Research and Education Program' has stimulated and assisted life sciences research and education at NASA's Johnson Space Center (JSC) - both at the Center and in collaboration with outside academic institutions. To accomplish our objectives, the DSLS has facilitated extramural research, developed and managed educational programs, recruited and employed visiting and staff scientists, and managed scientific meetings.

  20. Response to science education reforms: The case of three science education doctoral programs in the United States

    Science.gov (United States)

    Gwekwerere, Yovita Netsai

    Doctoral programs play a significant role in preparing future leaders. Science Education doctoral programs play an even more significant role preparing leaders in a field that is critical to maintaining national viability in the face of global competition. The current science education reforms have the goal of achieving science literacy for all students and for this national goal to be achieved; we need strong leadership in the field of science education. This qualitative study investigated how doctoral programs are preparing their graduates for leadership in supporting teachers to achieve the national goal of science literacy for all. A case study design was used to investigate how science education faculty interpreted the national reform goal of science literacy for all and how they reformed their doctoral courses and research programs to address this goal. Faculty, graduate students and recent graduates of three science education doctoral programs participated in the study. Data collection took place through surveys, interviews and analysis of course documents. Two faculty members, three doctoral candidates and three recent graduates were interviewed from each of the programs. Data analysis involved an interpretive approach. The National Research Council Framework for Investigating Influence of the National Standards on student learning (2002) was used to analyze interview data. Findings show that the current reforms occupy a significant part of the doctoral coursework and research in these three science education doctoral programs. The extent to which the reforms are incorporated in the courses and the way they are addressed depends on how the faculty members interpret the reforms and what they consider to be important in achieving the goal of science literacy for all. Whereas some faculty members take a simplistic critical view of the reform goals as a call to achieve excellence in science teaching; others take a more complex critical view where they question

  1. The Feasibility of Educating Trainee Science Teachers in Issues of Science and Religion

    Science.gov (United States)

    Poole, Michael

    2016-01-01

    This article reflects on Roussel De Carvalho's paper "Science initial teacher education and superdiversity: educating science teachers for a multi-religious and globalized science classroom" (EJ1102211). It then offers suggestions for making some of the ambitious goals of the science-and-religion components of the science initial teacher…

  2. Qualitative exploration of centralities in municipal science education networks

    DEFF Research Database (Denmark)

    von der Fehr, Ane; Sølberg, Jan

    2016-01-01

    This article examines the social nature of educational change by conducting a social network analysis of social networks involving stakeholders of science education from teachers to political stakeholders. Social networks that comprise supportive structures for development of science education ar...... of science education, especially if they are aware of their own centrality and are able to use their position intentionally for the benefit of science education.......This article examines the social nature of educational change by conducting a social network analysis of social networks involving stakeholders of science education from teachers to political stakeholders. Social networks that comprise supportive structures for development of science education...... are diverse and in order to understand how municipal stakeholders may support such development, we explored four different municipal science education networks (MSE networks) using three different measures of centrality. The centrality measures differed in terms of what kind of stakeholder functions...

  3. Scientism and Scientific Thinking. A Note on Science Education

    Science.gov (United States)

    Gasparatou, Renia

    2017-11-01

    The move from respecting science to scientism, i.e., the idealization of science and scientific method, is simple: We go from acknowledging the sciences as fruitful human activities to oversimplifying the ways they work, and accepting a fuzzy belief that Science and Scientific Method, will give us a direct pathway to the true making of the world, all included. The idealization of science is partly the reason why we feel we need to impose the so-called scientific terminologies and methodologies to all aspects of our lives, education too. Under this rationale, educational policies today prioritize science, not only in curriculum design, but also as a method for educational practice. One might expect that, under the scientistic rationale, science education would thrive. Contrariwise, I will argue that scientism disallows science education to give an accurate image of the sciences. More importantly, I suggest that scientism prevents one of science education's most crucial goals: help students think. Many of my arguments will borrow the findings and insights of science education research. In the last part of this paper, I will turn to some of the most influential science education research proposals and comment on their limits. If I am right, and science education today does not satisfy our most important reasons for teaching science, perhaps we should change not just our teaching strategies, but also our scientistic rationale. But that may be a difficult task.

  4. 75 FR 55805 - National Institute of Environmental Health Sciences; Notice of Meeting

    Science.gov (United States)

    2010-09-14

    ... Environmental Health Sciences; Notice of Meeting Pursuant to section 10(a) of the Federal Advisory Committee Act... Environmental Health Sciences, 615 Davis Dr., KEY615/3112, Research Triangle Park, NC 27709. (919) 541-4980... Environmental Health Sciences; 93.113, Biological Response to Environmental Health Hazards; 93.114, Applied...

  5. OceanGLOBE: an Outdoor Research and Environmental Education Program for K-12 Students

    Science.gov (United States)

    Perry, R. B.; Hamner, W. M.

    2006-12-01

    OceanGLOBE is an outdoor environmental research and education program for upper elementary, middle and high school students, supplemented by online instructional materials that are available without charge to any educator. OceanGLOBE was piloted in 1995 with support from a National Science Foundation Teacher Enhancement project, "Leadership in Marine Science" (award no.ESI-9454413 to UCLA). Continuing support by a second NSF Teacher Enhancement project (award no. ESI-9819424 to UCLA) and by COSEE-West (NSF awards OCE-215506 to UCLA and OCE-0215497 to USC) has enabled OceanGLOBE to expand to a growing number of schools and to provide an increasingly robust collection of marine science instructional materials on its website, http://www.msc.ucla.edu/oceanglobe/ OceanGLOBE provides a mechanism for students to conduct inquiry-based, hands-on marine science research, providing experiences that anchor the national and state science content standards learned in the classroom. Students regularly collect environmental and biological data from a beach site over an extended period of time. In the classroom they organize, graph and analyze their data, which can lead to a variety of student-created science products. Beach research is supported by instructional marine science materials on the OceanGLOBE website. These online materials also can be used in the classroom independent of the field component. Annotated PowerPoint slide shows explain research protocols and provide marine science content. Field guides and photographs of marine organisms (with emphasis on the Southern California Bight) and a growing collection of classroom investigations (applicable to any ocean location) support the science content presented in the beach research program and slide shows. In summary, OceanGLOBE is a comprehensive learning package grounded in hands-on, outdoor marine science research project in which students are the principal investigators. By doing scientific work repetitively over an

  6. Exploring Environmental Identity and Behavioral Change in an Environmental Science Course

    Science.gov (United States)

    Blatt, Erica N.

    2013-01-01

    This ethnographic study at a public high school in the Northeastern United States investigates the process of change in students' environmental identity and proenvironmental behaviors during an Environmental Science course. The study explores how sociocultural factors, such as students' background, social interactions, and classroom structures,…

  7. Southern African Journal of Environmental Education

    African Journals Online (AJOL)

    The Southern African Journal of Environmental Education (SAJEE) is an accredited and ... It is published at least once a year, by the Environmental Education Association of Southern Africa (EEASA). ... AJOL African Journals Online. HOW TO ...

  8. Communicating Ocean Sciences College Courses: Science Faculty and Educators Working and Learning Together

    Science.gov (United States)

    Halversen, C.; Simms, E.; McDonnell, J. D.; Strang, C.

    2011-12-01

    As the relationship between science and society evolves, the need for scientists to engage and effectively communicate with the public about scientific issues has become increasingly urgent. Leaders in the scientific community argue that research training programs need to also give future scientists the knowledge and skills to communicate. To address this, the Communicating Ocean Sciences (COS) series was developed to teach postsecondary science students how to communicate their scientific knowledge more effectively, and to build the capacity of science faculty to apply education research to their teaching and communicate more effectively with the public. Courses are co-facilitated by a faculty scientist and either a K-12 or informal science educator. Scientists contribute their science content knowledge and their teaching experience, and educators bring their knowledge of learning theory regarding how students and the public make meaning from, and understand, science. The series comprises two university courses for science undergraduate and graduate students that are taught by ocean and climate scientists at approximately 25 universities. One course, COS K-12, is team-taught by a scientist and a formal educator, and provides college students with experience communicating science in K-12 classrooms. In the other course, COSIA (Communicating Ocean Sciences to Informal Audiences), a scientist and informal educator team-teach, and the practicum takes place in a science center or aquarium. The courses incorporate current learning theory and provide an opportunity for future scientists to apply that theory through a practicum. COS addresses the following goals: 1) introduce postsecondary students-future scientists-to the importance of education, outreach, and broader impacts; 2) improve the ability of scientists to communicate science concepts and research to their students; 3) create a culture recognizing the importance of communicating science; 4) provide students and

  9. Publications in biomedical and environmental sciences programs, 1981

    Energy Technology Data Exchange (ETDEWEB)

    Moody, J.B. (comp.)

    1982-07-01

    This bibliography contains 698 references to articles in journals, books, and reports published in the subject area of biomedical and environmental sciences during 1981. There are 520 references to articles published in journals and books and 178 references to reports. Staff members in the Biomedical and Environmental Sciences divisions have other publications not included in this bibliography; for example, theses, book reviews, abstracts published in journals or symposia proceedings, pending journal publications and reports such as monthly, bimonthly, and quarterly progress reports, contractor reports, and reports for internal distribution. This document is sorted by the division, and then alphabetically by author. The sorting by divisions separates the references by subject area in a simple way. The divisions represented in the order that they appear in the bibliography are Analytical Chemistry, Biology, Chemical Technology, Information R and D, Health and Safety Research, Instrumentation and Controls, Computer Sciences, Energy, Engineering Technology, Solid State, Central Management, Operations, and Environmental Sciences. Indexes are provided by author, title, and journal reference.

  10. Publications in biomedical and environmental sciences programs, 1981

    International Nuclear Information System (INIS)

    Moody, J.B.

    1982-07-01

    This bibliography contains 698 references to articles in journals, books, and reports published in the subject area of biomedical and environmental sciences during 1981. There are 520 references to articles published in journals and books and 178 references to reports. Staff members in the Biomedical and Environmental Sciences divisions have other publications not included in this bibliography; for example, theses, book reviews, abstracts published in journals or symposia proceedings, pending journal publications and reports such as monthly, bimonthly, and quarterly progress reports, contractor reports, and reports for internal distribution. This document is sorted by the division, and then alphabetically by author. The sorting by divisions separates the references by subject area in a simple way. The divisions represented in the order that they appear in the bibliography are Analytical Chemistry, Biology, Chemical Technology, Information R and D, Health and Safety Research, Instrumentation and Controls, Computer Sciences, Energy, Engineering Technology, Solid State, Central Management, Operations, and Environmental Sciences. Indexes are provided by author, title, and journal reference

  11. New Swedish environmental and sustainable education research

    Directory of Open Access Journals (Sweden)

    Johan Öhman

    2011-01-01

    Full Text Available This special issue of Education & Democracy presents examples froma new generation of Swedish research on environmental and sustainability education and thereby complement the picture of the current Swedish environmental and sustainability education research outlined in the recent Danish-Swedish special issue of Environmental EducationResearch (Vol 16, No 1 and the anthology Democracy and Values inEducation for Sustainable Development – Contributions from Swedish Research (Öhman 2008. All the contributors to this issue are associatedwith the Graduate School in Education and Sustainable Development (GRESD, either as PhD students or as supervisors.

  12. Science and the Ideals of Liberal Education

    Science.gov (United States)

    Carson, Robert N.

    This article examines the influence of mathematics and science on the formation of culture. It then examines several definitions of liberal education, including the notion that languages and fields of study constitute the substrate of articulate intelligence. Finally, it examines the linkages between science, scientific culture, liberal education, and democracy, and proposes that science cannot be taught merely as a body of facts and theories, but must be presented to students as integral with cultural studies. The use of a contextualist approach to science education is recommended.

  13. Tourism and Environmental Education.

    Science.gov (United States)

    Mason, Peter

    1994-01-01

    Proposes that tourism should be part of the environmental education curriculum. Discusses the significance of tourism, the impacts of tourism on the environment, the concept of sustainable tourism, and tourism in education in the United Kingdom. (MDH)

  14. A Computer Learning Center for Environmental Sciences

    Science.gov (United States)

    Mustard, John F.

    2000-01-01

    In the fall of 1998, MacMillan Hall opened at Brown University to students. In MacMillan Hall was the new Computer Learning Center, since named the EarthLab which was outfitted with high-end workstations and peripherals primarily focused on the use of remotely sensed and other spatial data in the environmental sciences. The NASA grant we received as part of the "Centers of Excellence in Applications of Remote Sensing to Regional and Global Integrated Environmental Assessments" was the primary source of funds to outfit this learning and research center. Since opening, we have expanded the range of learning and research opportunities and integrated a cross-campus network of disciplines who have come together to learn and use spatial data of all kinds. The EarthLab also forms a core of undergraduate, graduate, and faculty research on environmental problems that draw upon the unique perspective of remotely sensed data. Over the last two years, the Earthlab has been a center for research on the environmental impact of water resource use in and regions, impact of the green revolution on forest cover in India, the design of forest preserves in Vietnam, and detailed assessments of the utility of thermal and hyperspectral data for water quality analysis. It has also been used extensively for local environmental activities, in particular studies on the impact of lead on the health of urban children in Rhode Island. Finally, the EarthLab has also served as a key educational and analysis center for activities related to the Brown University Affiliated Research Center that is devoted to transferring university research to the private sector.

  15. Biological sciences teaching undergraduates’ environmental knowledge: a critical analysis

    Directory of Open Access Journals (Sweden)

    Silvana do Nascimento Silva

    2013-12-01

    Full Text Available Nowadays, environmental issues have been addressed in a way that goes beyond the natural impacts, embracing socio-economic, political and cultural aspects. This paper makes a description of the types of environmental conceptions, giving special emphasis to the interactions that permeate it, and develops an empirical work by analyzing the conceptions about the environmental knowledge of students majoring in a teacher preparation course on biological sciences of a university in the State of Bahia, Brazil. In a qualitative research, data were collected by application of a questionnaire with open questions with answers in text and drawings. The results revealed a predominance of naturalistic conceptions, while socio-environmental conceptions of systemic or socio-metabolic characteristics were not found. These findings lead to the need for the integration of these critical approaches about the environmental issue in Sciences and Biology teachers’ training, emphasizing the interactions between work, nature and society. Finally, some suggestions also emerge for future research, among which to analyze the biological sciences university teachers’ environmental conceptions and an action-research with these investigated undergraduates concerning environmental critical approaches.

  16. The Globalization of Science Education

    Science.gov (United States)

    Deboer, George

    2012-02-01

    Standards-based science education, with its emphasis on clearly stated goals, performance monitoring, and accountability, is rapidly becoming a key part of how science education is being viewed around the world. Standards-based testing within countries is being used to determine the effectiveness of a country's educational system, and international testing programs such as PISA and TIMSS enable countries to compare their students to a common standard and to each other. The raising of standards and the competition among countries is driven in part by a belief that economic success depends on a citizenry that is knowledgeable about science and technology. In this talk, I consider the question of whether it is prudent to begin conversations about what an international standards document for global citizenship in science education might look like. I examine current practices to show the areas of international agreement and the significant differences that still exist, and I conclude with a recommendation that such conversations should begin, with the goal of laying out the knowledge and competencies that international citizens should have that also gives space to individual countries to pursue goals that are unique to their own setting.

  17. Exploring the Effects of Communication Framed by Environmental Concern in Informal Science Education Contexts

    Science.gov (United States)

    Yocco, Victor S.

    2010-01-01

    Informal science education (ISE) venues such as zoos, nature centers, parks, and natural history museums play a critical role in allowing the general public to learn scientific concepts (National Research Council, 2009; 2010). Most adult learning of scientific concepts takes place outside of classrooms and away from work (Rennie and Williams,…

  18. A Reconstructed Vision of Environmental Science Literacy: The Case of Qatar

    Science.gov (United States)

    Khishfe, Rola

    2014-01-01

    The purpose of this study was twofold: (a) develop a conceptual framework for environmental science literacy; and consequently (b) examine the potential of science standards/curricula to prepare environmentally literate citizens. The framework comprised four pillars: science content knowledge, scientific inquiry, nature of science (NOS), and…

  19. Environmental science and technology

    International Nuclear Information System (INIS)

    2014-01-01

    The Program on Environmental Science and Technology developed at the Chemical and Environmental Technology Center comprehends environmental chemistry (water, soil and atmospheric chemistry), clean technologies (desulfurization of diesel and oil, biodegradable polymers and structural modification of polymers, recycling, pyrolysis of dangerous chemicals by molten salt technology), nanotechnology (magnetic nanoparticles, dendrimers, nano biomarkers, catalysts) and chemical characterization of nuclear fuel and nuclear fuel cycle waste (chemical and isotopic characterization). The Chemical and Environmental Technology Center was established in 1995, as an evolution of the former Department of Chemistry Engineering (1970). The program on environment science and technology was structured as consequence of the continuous growth of environmental activities on areas related to nuclear programs of IPEN. Moreover, it was an answer to the society concerning the climate changes and biodiversity preservation. All activities of research and development, services, supervision of graduate and under graduated students and courses performance at the center were related to the development, improvement and establishment of new technologies. The highlights of this period (2011 - 2013) were: - Development and use of modern analytical technology for the characterization of persistent pollutants and endocrine disrupters (metals, PAHA’s, PCBs, Pesticides, hormones, surfactants, plasticizer and human pharmaceuticals) in order to evaluate water quality and/or sediments; - Atmospheric chemistry and greenhouse gases: Evaluating an estimation of surface trace gas fluxes from aircraft measurements above the Amazon; - Cooperation with SABESP (Water and Sewage Company) and CETESB (State Environment Agency) in program for the development of public policies; - Studies and development in biodegradable polymers, polyolefins and advanced methods for polymer and rubber recycling and re-use; - Studies

  20. Environmental science and technology

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2014-07-01

    The Program on Environmental Science and Technology developed at the Chemical and Environmental Technology Center comprehends environmental chemistry (water, soil and atmospheric chemistry), clean technologies (desulfurization of diesel and oil, biodegradable polymers and structural modification of polymers, recycling, pyrolysis of dangerous chemicals by molten salt technology), nanotechnology (magnetic nanoparticles, dendrimers, nano biomarkers, catalysts) and chemical characterization of nuclear fuel and nuclear fuel cycle waste (chemical and isotopic characterization). The Chemical and Environmental Technology Center was established in 1995, as an evolution of the former Department of Chemistry Engineering (1970). The program on environment science and technology was structured as consequence of the continuous growth of environmental activities on areas related to nuclear programs of IPEN. Moreover, it was an answer to the society concerning the climate changes and biodiversity preservation. All activities of research and development, services, supervision of graduate and under graduated students and courses performance at the center were related to the development, improvement and establishment of new technologies. The highlights of this period (2011 - 2013) were: - Development and use of modern analytical technology for the characterization of persistent pollutants and endocrine disrupters (metals, PAHA’s, PCBs, Pesticides, hormones, surfactants, plasticizer and human pharmaceuticals) in order to evaluate water quality and/or sediments; - Atmospheric chemistry and greenhouse gases: Evaluating an estimation of surface trace gas fluxes from aircraft measurements above the Amazon; - Cooperation with SABESP (Water and Sewage Company) and CETESB (State Environment Agency) in program for the development of public policies; - Studies and development in biodegradable polymers, polyolefins and advanced methods for polymer and rubber recycling and re-use; - Studies

  1. A New Vision for Chemistry Education Students: Environmental Education

    Science.gov (United States)

    Teksoz, Gaye; Sahin, Elvan; Ertepinar, Hamide

    2010-01-01

    The present study aimed to determine level of pre-service chemistry teachers' environmental literacy and their perceptions on environmental education. This study was realized during the fall semester of 2006-2007 academic year with the participation of 60 students enrolled in five-year chemistry teacher education program. The data collected by…

  2. Environmental science-policy interactions

    DEFF Research Database (Denmark)

    Kamelarczyk, Kewin Bach Friis

    + (Reduced Emissions from Deforestation and forest Degradation and enhancement of forest carbon stocks) process and the phenomenon of deforestation in Zambia as research examples. The research was carried out from mid 2008 and to mid 2013 and applies a mixed methods research design. Fieldwork was carried out...... to science? This PhD thesis contributes to answering this questions; however it does this by questioning the conceptions of science that contribute to political decision-making and by exploring the relationship between scientific knowledge, other types of knowledge and policy. This PhD study employs the REDD...... in future REDD+ design and implementation. To curtail potential negative consequences of the identified mode of science-policy interaction in Zambia, the study concludes by making a number of proposals. The proposals are generic in nature and may be found relevant in environmental policy processes outside...

  3. Current Status of Regulatory Science Education in Faculties of Pharmaceutical Science in Japan.

    Science.gov (United States)

    Tohkin, Masahiro

    2017-01-01

    I introduce the current pharmaceutical education system in Japan, focusing on regulatory science. University schools or faculties of pharmaceutical science in Japan offer two courses: a six-year course for pharmacists and a four-year course for scientists and technicians. Students in the six-year pharmaceutical course receive training in hospitals and pharmacies during their fifth year, and those in the four-year life science course start research activities during their third year. The current model core curriculum for pharmaceutical education requires them to "explain the necessity and significance of regulatory science" as a specific behavior object. This means that pharmacists should understand the significance of "regulatory science", which will lead to the proper use of pharmaceuticals in clinical practice. Most regulatory science laboratories are in the university schools or faculties of pharmaceutical sciences; however, there are too few to conduct regulatory science education. There are many problems in regulatory science education, and I hope that those problems will be resolved not only by university-based regulatory science researchers but also by those from the pharmaceutical industry and regulatory authorities.

  4. Science Instructors' Perceptions of the Risks of Biotechnology: Implications for Science Education

    Science.gov (United States)

    Gardner, Grant Ean; Jones, M. Gail

    2011-01-01

    Developing scientifically literate students who understand the socially contextualized nature of science and technology is a national focus of science education reform. Science educators' perceptions of risks and benefits of new technologies (such as biotechnology) may shape their instructional approaches. This study examined the perceived risk of…

  5. Imaginative science education the central role of imagination in science education

    CERN Document Server

    Hadzigeorgiou, Yannis

    2016-01-01

    This book is about imaginative approaches to teaching and learning school science. Its central premise is that science learning should reflect the nature of science, and therefore be approached as an imaginative/creative activity. As such, the book can be seen as an original contribution of ideas relating to imagination and creativity in science education. The approaches discussed in the book are storytelling, the experience of wonder, the development of ‘romantic understanding’, and creative science, including science through visual art, poetry and dramatization. However, given the perennial problem of how to engage students (of all ages) in science, the notion of ‘aesthetic experience’, and hence the possibility for students to have more holistic and fulfilling learning experiences through the aforementioned imaginative approaches, is also discussed. Each chapter provides an in-depth discussion of the theoretical background of a specific imaginative approach (e.g., storytelling, ‘wonder-full’ s...

  6. Panarchy use in environmental science for risk and resilience ...

    Science.gov (United States)

    Environmental sciences have an important role in informing sustainable management of built environments by providing insights about the drivers and potentially negative impacts of global environmental change. Here, we discuss panarchy theory, a multi-scale hierarchical concept that accounts for the dynamism of complex socio-ecological systems, especially for those systems with strong cross-scale feedbacks. The idea of panarchy underlies much of system resilience, focusing on how systems respond to known and unknown threats. Panarchy theory can provide a framework for qualitative and quantitative research and application in the environmental sciences, which can in turn inform the ongoing efforts in socio-technical resilience thinking and adaptive and transformative approaches to management. The environmental sciences strive for understanding, mitigating and reversing the negative impacts of global environmental change, including chemical pollution, to maintain sustainability options for the future, and therefore play an important role for informing management.

  7. Constructing Artificial Rock Outcrops as Tools for Fostering Earth and Environmental Science Thinking

    Science.gov (United States)

    Totten, I. M.; Hall, F.; Buxton, C.

    2004-12-01

    The Earth and Environmental Science Education Group at the University of New Orleans has created an innovative visualization teaching tool. Through funding made available by the National Science Foundation a 12'x10'x5' artificial rock outcrop was fabricated at the University of New Orleans. An accompanying curriculum, which includes a series of artificial rock outcrop labs, was also created for the outcrop. The labs incorporated fundamental concepts from the geosciences and the field of science education. The overarching philosophy behind the unity of the content knowledge and the pedagogy was to develop a more inclusive and deliberate teaching approach that utilized strategies known to enhance student learning in the sciences. The artificial outcrop lab series emphasized the following geoscience topics: relative dating, rock movement, and depositional environments. The series also integrated pedagogical ideas such as inquiry-based learning, conceptual mapping, constructivist teaching, pattern recognition, and contextualized knowledge development. Each component of the curriculum was purposefully designed to address what the body of research in science education reveals as critical to science teaching and learning. After developing the artificial rock outcrop curriculum a pilot study was done with 40 pre-service elementary education undergraduates. In the pilot study students completed the following assessments: three outcrop labs, journal reflections for each lab, pre/post attitude surveys, group video-recordings, and preconception and final interviews. Data from these assessments were analyzed using qualitative and quantitative methodologies. The following conclusions were revealed from the data: student's attitudes towards learning earth science increased after working with the artificial rock outcrop, students conceptual understanding of the concepts were clearer after working with the outcrop, students were able to answer multifaceted, higher order questions

  8. On the way to a philosophy of science education

    Science.gov (United States)

    Schulz, Roland M.

    This Thesis argues the case that a philosophy of science education is required for improving science education as a research field as well as curriculum and teacher pedagogy. It seeks to re-think science education as an educational endeavor by examining why past reform efforts have been only partially successful, including why the fundamental goal of achieving scientific literacy after several "reform waves" has proven to be so elusive. The identity of such a philosophy is first defined in relation to the fields of philosophy, philosophy of science, and philosophy of education. Considering science education as a research discipline it is emphasized a new field should be broached with the express purpose of developing a discipline-specific "philosophy of science education" (largely neglected since Dewey). A conceptual shift towards the philosophy of education. is needed, thereto, on developing and demarcating true educational theories which could in addition serve to reinforce science education's growing sense of academic autonomy and independence from socio-economic demands. Two educational metatheories are contrasted, those of Kieran Egan and the Northern European Bildung tradition, to illustrate the task of such a philosophy. Egan's cultural-linguistic metatheory is presented for two primary purposes: it is offered as a possible solution to the deadlock of the science literacy conceptions within the discipline; regarding practice, examples are provided how it can better guide the instructional practice of teachers, specifically how it reinforces the work of other researchers in the History and Philosophy of Science (HPS) reform movement who value narrative in learning science. Considering curriculum and instruction, a philosophy of science education is conceptualized as a "second order" reflective capacity of the teacher. This notion is aligned with Shulman's idea of Pedagogical Content Knowledge. It is argued that for educators the nature of science learning

  9. College and university environmental programs as a policy problem (Part 1): Integrating Knowledge, education, and action for a better world?

    Science.gov (United States)

    Clark, S.G.; Rutherford, M.B.; Auer, M.R.; Cherney, D.N.; Wallace, R.L.; Mattson, D.J.; Clark, D.A.; Foote, L.; Krogman, N.; Wilshusen, P.; Steelman, T.

    2011-01-01

    The environmental sciences/studies movement, with more than 1000 programs at colleges and universities in the United States and Canada, is unified by a common interest-ameliorating environmental problems through empirical enquiry and analytic judgment. Unfortunately, environmental programs have struggled in their efforts to integrate knowledge across disciplines and educate students to become sound problem solvers and leaders. We examine the environmental program movement as a policy problem, looking at overall goals, mapping trends in relation to those goals, identifying the underlying factors contributing to trends, and projecting the future. We argue that despite its shared common interest, the environmental program movement is disparate and fragmented by goal ambiguity, positivistic disciplinary approaches, and poorly rationalized curricula, pedagogies, and educational philosophies. We discuss these challenges and the nature of the changes that are needed in order to overcome them. In a subsequent article (Part 2) we propose specific strategies for improvement. ?? 2011 Springer Science+Business Media, LLC.

  10. Science education policy for emergency, conflict, and post-conflict: An analysis of trends and implications for the science education program in Uganda

    Science.gov (United States)

    Udongo, Betty Pacutho

    This study analyzes the impact of armed conflicts on the development of education policy and particularly science education program in Uganda. Since independence from the British colonial rule, Uganda has experienced a series of armed conflicts, with the most devastating being the 21 years of conflict in Northern Uganda. The research study was guided by the following questions: (1) What is the level of government funding towards improving science education program in Uganda? (2) Have recent initiatives, such as free Primary and Secondary education, compulsory science, and 75% sponsorship for science-based courses, had a measurable impact on the proportion of students from the conflict-affected regions who enter tertiary institutions to pursue science and technology programs? (3) To what extent do the Ugandan Education Policy and, in particular, the Science Education Policy effectively address the educational needs of students affected by armed conflicts? The study employed a mixed method design where both quantitative and qualitative data were collected and analyzed. Quantitative data were obtained from a comprehensive search of policy documents and content analysis of literature on education policy, science education programs, and impact of conflicts on educational delivery. Qualitative data were obtained from surveys and interviews distributed to policy makers, central government and the local government officials, teachers, and students from the war-ravaged Northern Uganda. Analysis of policy documents and respondents' views revealed that Uganda does not have a science education policy, and the present education policy does not fully address the educational needs of students studying in conflict-affected regions. It was further observed that fewer students from the conflict-affected regions qualify for government scholarship to study science courses in higher institutions of learning. The study recommended the following policy interventions: (a) affirmative

  11. Integrating local environmental research into K-12 science classrooms and the value of graduate student-educator partnerships

    Science.gov (United States)

    Ward, N. D.; Petrik-Finley, R.

    2015-12-01

    Collaboration between researchers and K-12 educators enables an invaluable exchange of teaching philosophies and educational tools. Programs that partner graduate students with K-12 educators serve the dual purpose of training future educators and providing K-12 students with unique opportunities and perspectives. The benefits of this type of partnership include providing students with enhanced educational experiences and positive student-mentor relationships, training STEM graduate students in effective teaching strategies, and providing teachers with a firsthand resource for scientific information and novel educational materials. Many high school students have had little exposure to science beyond the classroom. Frequent interactions with "real-life" scientists can help make science more approachable and is an effective strategy for promoting science as a career. Here I describe my experiences and several lessons designed as a NSK GK-12 fellow. For example, a month-long unit on biogeochemical principles was framed as a crime scene investigation of a fish kill event in Hood Canal, Washington, in which students were given additional pieces of evidence to solve the mystery as they satisfied checkpoints in their understanding of key concepts. The evidence pieces included scientific plots, maps, datasets, and laboratory exercises. A clear benefit of this investigation-style unit is that students were able to learn the material at their individual pace. This structure allowed for a streamlined integration of differentiated materials such as simplified background readings or visual learning aids for struggling students or more detailed news articles and primary literature for more advanced students. Although the NSF GK-12 program has been archived, educators and researchers should pursue new partnerships, leveraging local and state-level STEM outreach programs with the goal of increasing national exposure of the societal benefits of such synergistic activities.

  12. The Utility of a Physics Education in Science Policy

    Science.gov (United States)

    Roberts, Drew

    2016-03-01

    In order for regulators to create successful policies on technical issues, ranging from environmental protection to distribution of national Grant money, the scientific community must play an integral role in the legislative process. Through a summer-long internship with the Science, Space, and Technology Committee of the U.S. House of Representatives, I have learned that skills developed while pursuing an undergraduate degree in physics are very valuable in the policy realm. My physics education provided me the necessary tools to bridge the goals of the scientific and political communities. The need for effective comprehension and communication of technical subjects provides an important opportunity for individuals with physics degrees to make substantial contributions to government policy. Science policy should be encouraged as one of the many career pathways for physics students. Society of Physics Students, John and Jane Mather Foundation for Science and the Arts.

  13. Promoting Science in Secondary School Education.

    Science.gov (United States)

    Chiovitti, Anthony; Duncan, Jacinta C; Jabbar, Abdul

    2017-06-01

    Engaging secondary school students with science education is crucial for a society that demands a high level of scientific literacy in order to deal with the economic and social challenges of the 21st century. Here we present how parasitology could be used to engage and promote science in secondary school students under the auspice of a 'Specialist Centre' model for science education. Copyright © 2017 Elsevier Ltd. All rights reserved.

  14. Special Education Teachers' Nature of Science Instructional Experiences

    Science.gov (United States)

    Mulvey, Bridget K.; Chiu, Jennifer L.; Ghosh, Rajlakshmi; Bell, Randy L.

    2016-01-01

    Special education teachers provide critical science instruction to students. However, little research investigates special education teacher beliefs and practices around science in general or the nature of science and inquiry in particular. This investigation is a cross-case analysis of four elementary special education teachers' initial…

  15. Science Education and Public Outreach Forums (SEPOF): Providing Coordination and Support for NASA's Science Mission Directorate Education and Outreach Programs

    Science.gov (United States)

    Mendez, B. J.; Smith, D.; Shipp, S. S.; Schwerin, T. G.; Stockman, S. A.; Cooper, L. P.; Peticolas, L. M.

    2009-12-01

    NASA is working with four newly-formed Science Education and Public Outreach Forums (SEPOFs) to increase the overall coherence of the Science Mission Directorate (SMD) Education and Public Outreach (E/PO) program. SEPOFs support the astrophysics, heliophysics, planetary and Earth science divisions of NASA SMD in three core areas: * E/PO Community Engagement and Development * E/PO Product and Project Activity Analysis * Science Education and Public Outreach Forum Coordination Committee Service. SEPOFs are collaborating with NASA and external science and education and outreach communities in E/PO on multiple levels ranging from the mission and non-mission E/PO project activity managers, project activity partners, and scientists and researchers, to front line agents such as naturalists/interpreters, teachers, and higher education faculty, to high level agents such as leadership at state education offices, local schools, higher education institutions, and professional societies. The overall goal for the SEPOFs is increased awareness, knowledge, and understanding of scientists, researchers, engineers, technologists, educators, product developers, and dissemination agents of best practices, existing NASA resources, and community expertise applicable to E/PO. By coordinating and supporting the NASA E/PO Community, the NASA/SEPOF partnerships will lead to more effective, sustainable, and efficient utilization of NASA science discoveries and learning experiences.

  16. 76 FR 50235 - National Institute of Environmental Health Sciences; Notice of Meetings

    Science.gov (United States)

    2011-08-12

    ... Environmental Health Sciences; Notice of Meetings Pursuant to section 10(a) of the Federal Advisory Committee... (DERT), Nat. Inst. of Environmental Health Sciences, National Institutes of Health, 615 Davis Dr... of Extramural Research and Training (DERT), Nat. Inst. of Environmental Health Sciences, National...

  17. 76 FR 7574 - National Institute of Environmental Health Sciences; Notice of Meetings

    Science.gov (United States)

    2011-02-10

    ... Environmental Health Sciences; Notice of Meetings Pursuant to section 10(a) of the Federal Advisory Committee... Cancer and Environmental Research Coordinating Committee State of the Science Subcommittee. These... Environmental Research Coordinating Committee (IBCERC) State of the Science Subcommittee. Date: March 29, 2011...

  18. Improving science education for sustainable development

    NARCIS (Netherlands)

    Eijck, van M.W.; Roth, W.-M.

    2007-01-01

    In recent issues of noteworthy journals, natural scientists have argued for the improvement of science education [1–4]. Such pleas reflect the growing awareness that high-quality science education is required not only for sustaining a lively scientific community that is able to address global

  19. Fermilab Friends for Science Education | Tree of Knowledge

    Science.gov (United States)

    Fermilab Friends for Science Education FFSE Home About Us Join Us Support Us Contact Us Tree of Testimonials Our Donors Board of Directors Board Tools Calendar Join Us Donate Now Get FermiGear! Education precollege science education programs. Prominently displayed at the Lederman Science Center is the lovely

  20. A Knowledge-Based Representation Scheme for Environmental Science Models

    Science.gov (United States)

    Keller, Richard M.; Dungan, Jennifer L.; Lum, Henry, Jr. (Technical Monitor)

    1994-01-01

    One of the primary methods available for studying environmental phenomena is the construction and analysis of computational models. We have been studying how artificial intelligence techniques can be applied to assist in the development and use of environmental science models within the context of NASA-sponsored activities. We have identified several high-utility areas as potential targets for research and development: model development; data visualization, analysis, and interpretation; model publishing and reuse, training and education; and framing, posing, and answering questions. Central to progress on any of the above areas is a representation for environmental models that contains a great deal more information than is present in a traditional software implementation. In particular, a traditional software implementation is devoid of any semantic information that connects the code with the environmental context that forms the background for the modeling activity. Before we can build AI systems to assist in model development and usage, we must develop a representation for environmental models that adequately describes a model's semantics and explicitly represents the relationship between the code and the modeling task at hand. We have developed one such representation in conjunction with our work on the SIGMA (Scientists' Intelligent Graphical Modeling Assistant) environment. The key feature of the representation is that it provides a semantic grounding for the symbols in a set of modeling equations by linking those symbols to an explicit representation of the underlying environmental scenario.

  1. Wisconsin Earth and Space Science Education

    Science.gov (United States)

    Bilbrough, Larry (Technical Monitor); French, George

    2003-01-01

    The Wisconsin Earth and Space Science Education project successfilly met its objectives of creating a comprehensive online portfolio of science education curricular resources and providing a professional development program to increase educator competency with Earth and Space science content and teaching pedagogy. Overall, 97% of participants stated that their experience was either good or excellent. The favorable response of participant reactions to the professional development opportunities highlights the high quality of the professional development opportunity. The enthusiasm generated for using the curricular material in classroom settings was overwhelmingly positive at 92%. This enthusiasm carried over into actual classroom implementation of resources from the curricular portfolio, with 90% using the resources between 1-6 times during the school year. The project has had a positive impact on student learning in Wisconsin. Although direct measurement of student performance is not possible in a project of this kind, nearly 75% of participating teachers stated that they saw an increase in student performance in math and science as a result of using project resources. Additionally, nearly 75% of participants saw an increase in the enthusiasm of students towards math and science. Finally, some evidence exists that the professional development academies and curricular portfolio have been effective in changing educator behavior. More than half of all participants indicated that they have used more hands-on activities as a result of the Wisconsin Earth and Space Science Education project.

  2. 1998 Environmental Management Science Program Annual Report

    International Nuclear Information System (INIS)

    1999-01-01

    The Environmental Management Science Program (EMSP) is a collaborative partnership between the DOE Office of Environmental Management (EM), Office of Science (DOE-SC), and the Idaho Operations Office (DOE-ID) to sponsor basic environmental and waste management related research. Results are expected to lead to reduction of the costs, schedule, and risks associated with cleaning up the nation's nuclear complex. The EMSP research portfolio addresses the most challenging technical problems of the EM program related to high level waste, spent nuclear fuel, mixed waste, nuclear materials, remedial action, decontamination and decommissioning, and health, ecology, or risk. The EMSP was established in response to a mandate from Congress in the fiscal year 1996 Energy and Water Development Appropriations Act. Congress directed the Department to ''provide sufficient attention and resources to longer-term basic science research which needs to be done to ultimately reduce cleanup costs, develop a program that takes advantage of laboratory and university expertise, and seek new and innovative cleanup methods to replace current conventional approaches which are often costly and ineffective''. This mandate followed similar recommendations from the Galvin Commission to the Secretary of Energy Advisory Board. The EMSP also responds to needs identified by National Academy of Sciences experts, regulators, citizen advisory groups, and other stakeholders

  3. 78 FR 18997 - National Institute of Environmental Health Sciences; Notice of Meeting

    Science.gov (United States)

    2013-03-28

    ... Environmental Health Sciences; Notice of Meeting Pursuant to section 10(d) of the Federal Advisory Committee Act... personnel issues. Place: Nat. Inst. of Environmental Health Sciences, Building 101, Rodbell Auditorium, 111.... Agenda: Poster Sessions. Place: Nat. Inst. of Environmental Health Sciences, Building 101, Rodbell...

  4. 76 FR 79201 - National Institute of Environmental Health Sciences; Notice of Meeting

    Science.gov (United States)

    2011-12-21

    ... Environmental Health Sciences; Notice of Meeting Pursuant to section 10(a) of the Federal Advisory Committee Act...: Nat. Inst. of Environmental Health Sciences, Building 101, Rodbell Auditorium, 111 T. W. Alexander...., Director, Division of Extramural Research and Training, Nat. Inst. of Environmental Health Sciences...

  5. 77 FR 26300 - National Institute of Environmental Health Sciences; Notice of Meeting

    Science.gov (United States)

    2012-05-03

    ... Environmental Health Sciences; Notice of Meeting Pursuant to section 10(d) of the Federal Advisory Committee Act... Structural Biology. Place: Nat. Inst. of Environmental Health Sciences, Building 101, Rodbell Auditorium, 111... Environmental Health Sciences, Building 101, Rodbell Auditorium, 111 T. W. Alexander Drive, Research Triangle...

  6. 76 FR 7572 - National Institute of Environmental Health Sciences; Notice of Meetings

    Science.gov (United States)

    2011-02-10

    ... Environmental Health Sciences; Notice of Meetings Pursuant to section 10(a) of the Federal Advisory Committee..., Director, Division of Extramural Research and Training, National Institute of Environmental Health Sciences... of Environmental Health Sciences, 615 Davis Dr., KEY615/3112, Research Triangle Park, NC 27709, (919...

  7. 76 FR 50234 - National Institute of Environmental Health Sciences Notice of Meetings

    Science.gov (United States)

    2011-08-12

    ... Environmental Health Sciences Notice of Meetings Pursuant to section 10(a) of the Federal Advisory Committee Act... of Extramural Research and Training (DERT), Nat. Inst. of Environmental Health Sciences, National..., Division of Extramural Research and Training (DERT), Nat. Inst. of Environmental Health Sciences, National...

  8. 78 FR 26643 - National Institute of Environmental Health Sciences; Notice of Meeting

    Science.gov (United States)

    2013-05-07

    ... Environmental Health Sciences; Notice of Meeting Pursuant to section 10(d) of the Federal Advisory Committee Act... Epidemiology Group and Biomarker-Based Epidemiology Group. Place: Nat. Inst. of Environmental Health Sciences.... Place: Nat. Inst. of Environmental Health Sciences, Building 101, Rodbell Auditorium, 111 T. W...

  9. 75 FR 7487 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2010-02-19

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory..., Scientific Review Administrator, National Inst. of Environmental Health Sciences, Office of Program... Manpower Development in the Environmental Health Sciences; 93.113, Biological Response to Environmental...

  10. ETHICS AND JUSTICE IN ENVIRONMENTAL SCIENCE AND ENGINEERING

    Science.gov (United States)

    Science and engineering are built on trust. C.P. Snow's famous quote, "the only ethical principle which has made science possible is that the truth shall be told all the time" underscores the importance of honesty in science. Environmental scientists must do work that is useful...

  11. The Role of Critical Thinking in Science Education

    Science.gov (United States)

    Santos, Luis Fernando

    2017-01-01

    This review aims to respond various questions regarding the role of Critical Thinking in Science Education from aspects concerning the importance or relevance of critical thinking in science education, the situation in the classroom and curriculum, and the conception of critical thinking and fostering in science education. This review is specially…

  12. The New England Space Science Initiative in Education (NESSIE)

    Science.gov (United States)

    Waller, W. H.; Clemens, C. M.; Sneider, C. I.

    2002-12-01

    Founded in January 2002, NESSIE is the NASA/OSS broker/facilitator for education and public outreach (E/PO) within the six-state New England region. NESSIE is charged with catalyzing and fostering collaborations among space scientists and educators within both the formal and informal education communities. NESSIE itself is a collaboration of scientists and science educators at the Museum of Science, Harvard-Smithsonian Center for Astrophysics, and Tufts University. Its primary goals are to 1) broker partnerships among space scientists and educators, 2) facilitate a wide range of educational and public outreach activities, and 3) examine and improve space science education methods. NESSIE's unique strengths reside in its prime location (the Museum of Science), its diverse mix of scientists and educators, and its dedicated board of advisors. NESSIE's role as a clearinghouse and facilitator of space science education is being realized through its interactive web site and via targeted meetings, workshops, and conferences involving scientists and educators. Special efforts are being made to reach underserved groups by tailoring programs to their particular educational needs and interests. These efforts are building on the experiences of prior and ongoing programs in space science education at the Museum of Science, the Harvard-Smithsonian Center for Astrophysics, Tufts University, and NASA.

  13. Science and Sanity in Special Education.

    Science.gov (United States)

    Dammann, James E.; Vaughn, Sharon

    2001-01-01

    This article describes the usefulness of a scientific approach to improving knowledge and practice in special education. Of four approaches to knowledge (superstition, folklore, craft, and science), craft and science are supported and implications for special education drawn including the need to bridge the gulf between research knowledge and…

  14. Developing Intercultural Science Education in Ecuador

    Science.gov (United States)

    Schroder, Barbara

    2008-01-01

    This article traces the recent development of intercultural science education in Ecuador. It starts by situating this development within the context of a growing convergence between Western and indigenous sciences. It then situates it within the larger historical, political, cultural, and educational contexts of indigenous communities in Ecuador,…

  15. 77 FR 66853 - National Institute of Environmental Health Sciences; Notice of Closed Meetings

    Science.gov (United States)

    2012-11-07

    ... Environmental Health Sciences; Notice of Closed Meetings Pursuant to section 10(d) of the Federal Advisory... Health Sciences Special Emphasis Panel Career Grants in the Environmental Health Sciences. Date: November...., Scientific Review Administrator, Nat. Institute of Environmental Health Sciences, Office of Program...

  16. 76 FR 80954 - National Institute of Environmental Health Sciences; Notice of Meeting

    Science.gov (United States)

    2011-12-27

    ... Environmental Health Sciences; Notice of Meeting Pursuant to section 10(a) of the Federal Advisory Committee Act.../boards/ibcercc/ . Place: Nat. Inst. of Environmental Health Sciences, Building 101, Rodbell Auditorium... Environmental Health Sciences, National Institutes of Health, 615 Davis Dr., KEY615/3112, Research Triangle Park...

  17. 75 FR 3474 - National Institute of Environmental Health Sciences; Notice of Meeting

    Science.gov (United States)

    2010-01-21

    ... Environmental Health Sciences; Notice of Meeting Pursuant to section 10(d) of the Federal Advisory Committee Act... Environmental Health Sciences Council. The meeting will be open to the public as indicated below, with... of Committee: National Advisory Environmental Health Sciences Council. Date: February 18-19, 2010...

  18. 75 FR 49500 - National Institute of Environmental Health Sciences; Notice of Meeting

    Science.gov (United States)

    2010-08-13

    ... Environmental Health Sciences; Notice of Meeting Pursuant to section 10(d) of the Federal Advisory Committee Act... Environmental Health Sciences Council. The meeting will be open to the public as indicated below, with... Committee: National Advisory Environmental Health Sciences Council. Date: September 1-2, 2010. Open...

  19. Can postpositivist research in environmental education engender ...

    African Journals Online (AJOL)

    In this article we contend that postpositivist research in environmental education can contribute towards promoting ethical activity within higher education. We argue that postpositivist inquiry breaks with utilitarian and uncritical assumptions about research in environmental education and also creates unconfined spaces for ...

  20. 75 FR 34147 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2010-06-16

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory... Review Branch, Division of Extramural Research and Training, Nat. Institute Environmental Health Sciences... Development in the Environmental Health Sciences; 93.113, Biological Response to Environmental Health Hazards...

  1. 78 FR 51734 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2013-08-21

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory..., Nat. Institute of Environmental Health Sciences, Office of Program Operations, Scientific Review... Development in the Environmental Health Sciences; 93.113, Biological Response to Environmental Health Hazards...

  2. 75 FR 32797 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2010-06-09

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory... Branch, Division of Extramural Research and Training, Nat. Institute of Environmental Health Sciences, P... Manpower Development in the Environmental Health Sciences; 93.113, Biological Response to Environmental...

  3. 78 FR 27410 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2013-05-10

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory..., Nat. Institute of Environmental Health Sciences, Office of Program Operations, Scientific Review... the Environmental Health Sciences; 93.113, Biological Response to Environmental Health Hazards; 93.114...

  4. Environmental management and monitoring for education building development

    Science.gov (United States)

    Masri, R. M.

    2018-05-01

    The purpose of research were (1) a conceptual, functional model designed and implementation for environmental management and monitoring for education building development, (2) standard operational procedure made for management and monitoring for education building development, (3) assessed physic-chemical, biological, social-economic environmental components so that fulfilling sustainable development, (4) environmental management and monitoring program made for decreasing negative and increasing positive impact in education building development activities. Descriptive method is used for the research. Cibiru UPI Campus, Bandung, West Java, Indonesia was study location. The research was conducted on July 2016 to January 2017. Spatial and activities analysis were used to assess physic-chemical, biological, social-economic environmental components. Environmental management and monitoring for education building development could be decreasing water, air, soil pollution and environmental degradation in education building development activities.

  5. The facts on file dictionary of environmental science

    Energy Technology Data Exchange (ETDEWEB)

    Stevenson, L.H.; Wyman, B. (eds.)

    1991-01-01

    More than 3000 entries of terms related to environmental science are included in this volume. The terms are defined in words meant to be understood by the nonexpert, for use in reporting to the general public. Definitions are one to two sentences in length and are accurate without being highly technical. The Appendix lists over 500 commonly used environmental science acronyms and abbreviations as well as a table of standard human factors.

  6. Inquiry-based science education

    DEFF Research Database (Denmark)

    Østergaard, Lars Domino; Sillasen, Martin Krabbe; Hagelskjær, Jens

    2010-01-01

    Inquiry-based science education (IBSE) er en internationalt afprøvet naturfagsdidaktisk metode der har til formål at øge elevernes interesse for og udbytte af naturfag. I artiklen redegøres der for metoden, der kan betegnes som en elevstyret problem- og undersøgelsesbaseret naturfagsundervisnings......Inquiry-based science education (IBSE) er en internationalt afprøvet naturfagsdidaktisk metode der har til formål at øge elevernes interesse for og udbytte af naturfag. I artiklen redegøres der for metoden, der kan betegnes som en elevstyret problem- og undersøgelsesbaseret...

  7. From Practice to Policy in Environmental Education

    African Journals Online (AJOL)

    practical skills that are needed to solve them. While infusion was the main focus of the country's environmental ... innovative work in the field of environmental education, thus recognising that additional thinking and experimentation are necessary to future policy formulation.The Uttarakhand. Environmental Education Centre ...

  8. African Journal of Educational Studies in Mathematics and Sciences

    African Journals Online (AJOL)

    African Journal of Educational Studies in Mathematics and Sciences. ... Studies in Mathematics and Sciences (AJESMS) is an international publication that ... in the fields of mathematics education, science education and related disciplines.

  9. Proceedings of the Science and Community Environmental Knowledge Fund forum

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2004-07-01

    This paper presented details of a forum which provided partners and stakeholders with an opportunity to see results of recent projects initiated by the Petroleum Technology Alliance Canada's Science and Community Environmental Knowledge Fund. The aim of the forum was to discuss future directions for research and funding. The fund is comprised of 5 knowledge envelopes covering environmental issues relevant to the oil and gas industry. These include ecosystem and cumulative impact management; health and safety; education and technology; and community environmental knowledge. Achievements, trends, challenges and innovations in environmental impact management were reviewed. Current environmental impact management strategies in British Columbia oil and gas industry were discussed along with issues concerning wildlife and footprint minimization in relation to facility operations and reclamation management. Waste and air quality management issues were also discussed. The forum featured 29 presentations that touched on topics such as innovations and opportunities in environmental impact research; Snake-Sahtaneh Boreal caribou habitat use and ecology; wildlife habitat connectivity and conservation of Peace River lowlands; mountain goats and helicopters; water use plan and low flow analysis; cumulative impacts assessment of development on forests and First Nations of northeast BC; geophysical line construction; the application of First Nations traditional knowledge to reclamation strategies in the oil and gas industry; issues concerning construction and standards; the influence of new technologies in environmental impact management; and the environmental aspects of natural gas midstream operations.

  10. Catalyzing Cross-Disciplinary Research and Education Within and Beyond the Environmental and Geosciences to Address Emerging, Societally-Relevant Issues

    Science.gov (United States)

    Cak, A. D.; Vigdor, L. J.; Vorosmarty, C. J.; Giebel, B. M.; Santistevan, C.; Chasteau, C.

    2017-12-01

    Tackling emergent, societally-relevant problems in the environmental sciences is hardly confined to a single research discipline, but rather requires collaborations that bridge diverse domains and perspectives. While new technologies (e.g., Skype) can in theory unite otherwise geographically distributed participation in collaborative research, physical distance nevertheless raises the bar on intellectual dialogue. Such barriers may reveal perceptions of or real differences across disciplines, reflecting particular traditions in their histories and academic cultures. Individual disciplines are self-defined by their scientific, epistemologic, methodologic, or philosophical traditions (e.g., difficulties in understanding processes occurring at different scales, insufficient research funding for interdisciplinary work), or cultural and discursive hurdles (e.g., navigating a new field's jargon). Coupled with these challenges is a considerable deficiency in educating the next generation of scientists to help them develop a sufficient comfort level with thinking critically across multiple disciplinary domains and conceptual frameworks. To address these issues, the City University of New York (CUNY), the largest public urban university in the U.S., made a significant investment in advancing cross-disciplinary research and education, culminating in the opening of the CUNY Advanced Science Research Center (ASRC) in New York City (NYC) in late 2014. We report here on our experiences incubating new collaborative efforts to address environmental science-related research as it is interwoven with the ASRC's five research initiatives (Environmental Sciences, Neuroscience, Structural Biology, Photonics, and Nanoscience). We describe the ASRC's overall structure and function as both a stand-alone interdisciplinary center and one that collaborates more broadly with CUNY's network of twenty-four campuses distributed across NYC's five boroughs. We identify challenges we have faced so

  11. van Eijck and Roth's utilitarian science education: why the recalibration of science and traditional ecological knowledge invokes multiple perspectives to protect science education from being exclusive

    Science.gov (United States)

    Mueller, Michael P.; Tippins, Deborah J.

    2010-12-01

    This article is a philosophical analysis of van Eijck and Roth's (2007) claim that science and traditional ecological knowledge (TEK) should be recalibrated because they are incommensurate, particular to the local contexts in which they are practical. In this view, science maintains an incommensurate status as if it is a "fundamental" basis for the relative comparison of other cultural knowledges, which reduces traditional knowledge to a status of in relation to the prioritized (higher)-status of natural sciences. van Eijck and Roth reject epistemological Truth as a way of thinking about sciences in science education. Rather they adopt a utilitarian perspective of cultural-historical activity theory to demonstrate when traditional knowledge is considered science and when it is not considered science, for the purposes of evaluating what should be included in U.S. science education curricula. There are several challenges for evaluating what should be included in science education when traditional knowledges and sciences are considered in light of a utilitarian analysis. Science as diverse, either practically local or theoretically abstract, is highly uncertain, which provides opportunities for multiple perspectives to enlarge and protect the natural sciences from exclusivity. In this response to van Eijck and Roth, we make the case for considering dialectical relationships between science and TEK in order to ensure cultural diversity in science education, as a paradigm. We also emphasize the need to (re)dissolve the hierarchies and dualisms that may emerge when science is elevated in status in comparison with other knowledges. We conclude with a modification to van Eijck and Roth's perspective by recommending a guiding principle of cultural diversity in science education as a way to make curriculum choices. We envision this principle can be applied when evaluating science curricula worldwide.

  12. 78 FR 42968 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2013-07-18

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory... Environmental Health Sciences, Building 101, Rodbell Auditorium, 111 T. W. Alexander Drive, Research Triangle... the Environmental Health Sciences; 93.113, Biological Response to Environmental Health Hazards; 93.114...

  13. 76 FR 46823 - National Institute of Environmental Health Sciences; Notice of Meeting

    Science.gov (United States)

    2011-08-03

    ... Environmental Health Sciences; Notice of Meeting Pursuant to section 10(d) of the Federal Advisory Committee Act... Environmental Health Sciences Council. The meeting will be open to the public as indicated below, with...: Discussion of program policies and issues. Place: Nat. Inst. of Environmental Health Sciences, Building 101...

  14. 76 FR 7225 - National Institute of Environmental Health Sciences; Notice of Meetings

    Science.gov (United States)

    2011-02-09

    ... Environmental Health Sciences; Notice of Meetings Pursuant to section 10(a) of the Federal Advisory Committee..., National Institute of Environmental Health Sciences, 615 Davis Dr., KEY615/3112, Research Triangle Park, NC..., National Institute of Environmental Health Sciences, 615 Davis Dr., KEY615/3112, Research Triangle Park, NC...

  15. 77 FR 3480 - National Institute of Environmental Health Sciences Notice of Meeting

    Science.gov (United States)

    2012-01-24

    ... Environmental Health Sciences Notice of Meeting Pursuant to section 10(d) of the Federal Advisory Committee Act... Environmental Health Sciences Council. The meeting will be open to the public as indicated below, with...: Discussion of program policies and issues. Place: Nat. Inst. of Environmental Health Sciences, Building 101...

  16. Initial teacher education and continuing professional development for science teachers

    DEFF Research Database (Denmark)

    Dolin, Jens; Evans, Robert Harry

    2011-01-01

    Research into ways of improving the initial education and continuing professional development of science teachers is closely related to both common and unique strands. The field is complex since science teachers teach at different educational levels, are often educated in different science subjects......, and belong to various cultures, both educationally and socially. Section 1 presents a review of the research literature across these dimensions and looks at the knowledge, skills and competences needed for teaching science, specific issues within science teacher education, and strategies for educating...... and developing science teachers....

  17. SPORTS SCIENCES AND MULTICULTURALISM - EDUCATIONAL AND PROFESSIONAL IMPACT

    Directory of Open Access Journals (Sweden)

    Danica Pirsl

    2012-09-01

    Full Text Available The aim of the paper is to familiarize the sports sciences educators to the pedagogic concept and professional benefits and awareness of multicultural education if implemented in sports sciences curricula, especially in the efforts to obtain international transparency through sports science literature writing and publishing. Data Sources were textbook chapters and articles searched through the archives of Diversity Digest and Academic Medicine for the years 2000 to 2005 with the key words multiculturalism, diversity, cultural competence, education, and learning. Synthesized data were used to present a rational argument for the inclusion of a critical pedagogy into the field of sports science education. The infrastructure in the professional field of sports sciences, review of the literature on critical multicultural theory and pedagogy and the potential cognitive and intellectual implications of diversity and multicultural education were analyzed. Conclusions/Recommendations focus on possible various and creative strategies for implementing a multicultural agenda in sports sciences curricula and on the analysis of the associated benefits and outcomes of such educational strategies.

  18. The Development of Environmental Conservation Youth Camping Using Environmental Education Process

    Directory of Open Access Journals (Sweden)

    Okrit Tee-ngarm

    2016-12-01

    Full Text Available The purposes of this research were: to make youths camp activities using environmental education process, to study and to compare the knowledge and attitude before and after the camp activities for conserving environment by using the process of environmental education. The sample were 30 youths in Mueng district, Sisaket province. The tools used in the research including activity manual, knowledge test, attitudes test and participation measurement. The data were analyzed by percentage, mean, standard deviation, and Paired t-test at significant level .05. The result showed that After camp activities for conserving environment by using the process of environmental education, the participats had mean score of knowledge and attitude toward environmental conservation at was higher than before the activities at statistical significantly level .05. And they had participation in youths camp activities for environmental conservation at the most level.

  19. 298 The Importance of Environmental Education to Secondary ...

    African Journals Online (AJOL)

    First Lady

    2013-01-28

    Jan 28, 2013 ... also discussed Environmental Education (EE) as a key to creating environmental .... The Development of Modern Education in Nigeria, ... of traditional education on Nigerian education system in Olukoya,. O. (Ed.) Culture and ...

  20. Trends of Science Education Research: An Automatic Content Analysis

    Science.gov (United States)

    Chang, Yueh-Hsia; Chang, Chun-Yen; Tseng, Yuen-Hsien

    2010-08-01

    This study used scientometric methods to conduct an automatic content analysis on the development trends of science education research from the published articles in the four journals of International Journal of Science Education, Journal of Research in Science Teaching, Research in Science Education, and Science Education from 1990 to 2007. The multi-stage clustering technique was employed to investigate with what topics, to what development trends, and from whose contribution that the journal publications constructed as a science education research field. This study found that the research topic of Conceptual Change & Concept Mapping was the most studied topic, although the number of publications has slightly declined in the 2000's. The studies in the themes of Professional Development, Nature of Science and Socio-Scientific Issues, and Conceptual Chang and Analogy were found to be gaining attention over the years. This study also found that, embedded in the most cited references, the supporting disciplines and theories of science education research are constructivist learning, cognitive psychology, pedagogy, and philosophy of science.

  1. 78 FR 8156 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2013-02-05

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory... Environmental Health Sciences Special Emphasis Panel; Studies of Environmental Agents to Induce Immunotoxicity... Research and Training, Nat. Institute of Environmental Health Sciences, P.O. Box 12233, MD EC-30, Research...

  2. 77 FR 40076 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2012-07-06

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory... Environmental Health Sciences, P.O. Box 12233, MD EC-30 Research Triangle Park, NC 27709, (919) 541- 0752... Manpower Development in the Environmental Health Sciences; 93.113, Biological Response to Environmental...

  3. Persuasion and Attitude Change in Science Education.

    Science.gov (United States)

    Koballa, Thomas R., Jr.

    1992-01-01

    Persuasion is presented as it may be applied by science educators in research and practice. The orientation taken is that science educators need to be acquainted with persuasion in the context of social influence and learning theory to be able to evaluate its usefulness as a mechanism for developing and changing science-related attitudes. (KR)

  4. Incorporating Geographic Information Science in the BSc Environ-mental Science Program in Botswana

    Science.gov (United States)

    Akinyemi, Felicia O.

    2018-05-01

    Critical human capacity in Geographic Information Science (GISc) is developed at the Botswana International University of Science and Technology, a specialized, research university. Strategies employed include GISc courses offered each semester to students from various programs, the conduct of field-based projects, enrolment in online courses, geo-spatial initiatives with external partners, and final year research projects utilizing geospatial technologies. A review is made of available GISc courses embedded in the Bachelor of Science Environmental Science program. GISc courses are incorporated in three Bachelor degree programs as distinct courses. Geospatial technologies are employed in several other courses. Student researches apply GIS and Remote Sensing methods to environmental and geological themes. The overarching goals are to equip students in various disciplines to utilize geospatial technologies, and enhance their spatial thinking and reasoning skills.

  5. Environmental Science and Technology department. Annual report 1991

    Energy Technology Data Exchange (ETDEWEB)

    Jensen, A.; Gunderson, V.; Hansen, H.; Gissel Nielsen, G.; Nielsen, O.J.; Oestergaard, H. [eds.

    1992-06-01

    Selected activities in the Environmental Science and Technology Department during 1991 are presented. The research approach in the department is predominantly experimental. The research topics emphasized are introduced and reviewed in chapters one to seven: 1. Introduction, 2. The Atmosphere, 3. Plant Genetics and Resistance Biology, 4. Plant Nutrition, 5. Geochemistry, 6. Ecology, 7. Other activities. The Department`s contribution to national and international collaborative research programmes is presented together with information about large facilities managed and used by the department. Information about the department`s education and training activities are included in the annual report along with lists of publications, publications in press, lectures and poster presentations. Further, names of the scientific and technical staff members, Ph.D. students and visiting scientists are listed. (au) (23 ills., 58 refs.).

  6. Environmental Science and Technology department. Annual report 1991

    Energy Technology Data Exchange (ETDEWEB)

    Jensen, A.; Gunderson, V.; Hansen, H.; Gissel Nielsen, G.; Nielsen, O.J.; Oestergaard, H. (eds.)

    1992-06-01

    Selected activities in the Environmental Science and Technology Department during 1991 are presented. The research approach in the department is predominantly experimental. The research topics emphasized are introduced and reviewed in chapters one to seven: 1. Introduction, 2. The Atmosphere, 3. Plant Genetics and Resistance Biology, 4. Plant Nutrition, 5. Geochemistry, 6. Ecology, 7. Other activities. The Department's contribution to national and international collaborative research programmes is presented together with information about large facilities managed and used by the department. Information about the department's education and training activities are included in the annual report along with lists of publications, publications in press, lectures and poster presentations. Further, names of the scientific and technical staff members, Ph.D. students and visiting scientists are listed. (au) (23 ills., 58 refs.).

  7. Environmental Science and Technology department. Annual report 1991

    International Nuclear Information System (INIS)

    Jensen, A.; Gunderson, V.; Hansen, H.; Gissel Nielsen, G.; Nielsen, O.J.; Oestergaard, H.

    1992-06-01

    Selected activities in the Environmental Science and Technology Department during 1991 are presented. The research approach in the department is predominantly experimental. The research topics emphasized are introduced and reviewed in chapters one to seven: 1. Introduction, 2. The Atmosphere, 3. Plant Genetics and Resistance Biology, 4. Plant Nutrition, 5. Geochemistry, 6. Ecology, 7. Other activities. The Department's contribution to national and international collaborative research programmes is presented together with information about large facilities managed and used by the department. Information about the department's education and training activities are included in the annual report along with lists of publications, publications in press, lectures and poster presentations. Further, names of the scientific and technical staff members, Ph.D. students and visiting scientists are listed. (au) (23 ills., 58 refs.)

  8. Environmental Education.

    Science.gov (United States)

    Heiser, Ed

    Furnished in this comprehensive report is a resume of a five-year experimental program in environmental education conducted by the Eastern Montana College Laboratory School in conjunction with Eastern Montana College and the Billings School District #2. The basic purpose of the program is to make teachers, and in turn students, aware of the…

  9. How Blogging on Earth and Environmental Science Changed One Student's Passion, Perception, and Future

    Science.gov (United States)

    Dufoe, A.

    2013-12-01

    In 2011, I started a WordPress blog to engage more with my undergraduate education field of study - communications. Starting out with blog posts about social media, this blog's initial goal was to showcase my interest in the media as well as to blog about my first conference attendance and presentations. However, blogging turned into more than that for me. As I was pursuing a minor in Environmental Inquiry and therefore taking more Earth and environmental science classes, I learned that I love to write about environmental issues, particularly about how issues can be addressed and resolved. Because of this shift in my personal and professional interests, I began to blog about global topics such as global water consumption, environmental conservation and arctic sea ice. This change in direction was unprecedented, but helped define my online presence. Over the two years I have been writing my blog, the science posts have been the most successful, with WordPress.com users liking and reading the posts. Readers from all over the globe are brought to my blog from search engines, as shown through the analytics on the WordPress dashboard. However, the impact of my blog on others is challenging to quantify apart from the analytics, because most people do not comment on the posts. Regardless, and most importantly, my blog has changed MY perception of science. Before I started blogging about science topics, I was unaware of how complicated and connected Earth's processes are, including climate change, natural disasters, human actions and pollution. Overall, this blog has been important to me because it helped define my interests academically, leading me to apply and be accepted to a Masters program at the University of Montana starting in August 2013. The program in Environmental Science and Natural Resource Journalism umbrellas over both my training in communications and my love for the environment. Because of my personal growth through my blog, I am also motivated to create

  10. Sensory Perception, Rationalism and Outdoor Environmental Education

    Science.gov (United States)

    Auer, Matthew R.

    2008-01-01

    There is a strong emphasis on sensory perception and "hands-on" learning in the outdoor environmental education of children. In addition, normative concerns infuse children's environmental curricula, and in particular, the notion that environmental education is not a passive undertaking; when one appreciates the essential value of the…

  11. The Particulate Nature of Matter in Science Education and in Science.

    Science.gov (United States)

    Vos, Wobbe de; Verdonk, Adri H.

    1996-01-01

    Discusses ideas about the particulate nature of matter and assesses the extent to which these represent a compromise between scientific and educational considerations. Analyzes relations between the particulate nature of matter in science and science education in an attempt to understand children's inclination to attribute all kinds of macroscopic…

  12. What is `Agency'? Perspectives in Science Education Research

    Science.gov (United States)

    Arnold, Jenny; Clarke, David John

    2014-03-01

    The contemporary interest in researching student agency in science education reflects concerns about the relevance of schooling and a shift in science education towards understanding learning in science as a complex social activity. The purpose of this article is to identify problems confronting the science education community in the development of this new research agenda and to argue that there is a need for research in science education that attends to agency as a social practice. Despite increasing interest in student agency in educational research, the term 'agency' has lacked explicit operationalisation and, across the varied approaches, such as critical ethnography, ethnographies of communication, discourse analysis and symbolic interactionism, there has been a lack of coherence in its research usage. There has also been argument concerning the validity of the use of the term 'agency' in science education research. This article attempts to structure the variety of definitions of 'student agency' in science education research, identifies problems in the research related to assigning intentionality to research participants and argues that agency is a kind of discursive practice. The article also draws attention to the need for researchers to be explicit in the assumptions they rely upon in their interpretations of social worlds. Drawing upon the discursive turn in the social sciences, a definition of agency is provided, that accommodates the discursive practices of both individuals and the various functional social groups from whose activities classroom practice is constituted. The article contributes to building a focused research agenda concerned with understanding and promoting student agency in science.

  13. Environmental Education Research: To What Ends?

    Science.gov (United States)

    Jickling, Bob

    2009-01-01

    This paper engages questions about ends in environmental education research. In doing so, I argue that such questions are essentially normative, and that normative questions are underrepresented in this field. After cautioning about perils of prescribing research agendas, I gently suggest that in environmental education key normative questions…

  14. Environmental Science Program at the Advanced Light Source

    Energy Technology Data Exchange (ETDEWEB)

    Hubbard, Susan; Shuh, David; Nico, Peter

    2005-06-01

    Synchrotron Radiation (SR)-based techniques have become an essential and fundamental research tool in Molecular Environmental Science (MES) research. MES is an emerging scientific field that has largely evolved from research interactions at the U.S. Department of Energy (U.S. DOE) SR laboratories in response to the pressing need for understanding fundamental molecular-level chemical and biological processes that involve the speciation, properties, and behavior of contaminants, within natural systems. The role of SR-based investigations in MES and their impact on environmental problems of importance to society has been recently documented in Molecular Environmental Science: An Assessment of Research Accomplishment, Available Synchrotron Radiation Facilities, and Needs (EnviroSync, 2003).

  15. When Nature of Science Meets Marxism: Aspects of Nature of Science Taught by Chinese Science Teacher Educators to Prospective Science Teachers

    Science.gov (United States)

    Wan, Zhi Hong; Wong, Siu Ling; Zhan, Ying

    2013-01-01

    Nature of science (NOS) is beginning to find its place in the science education in China. In a study which investigated Chinese science teacher educators' conceptions of teaching NOS to prospective science teachers through semi-structured interviews, five key dimensions emerged from the data. This paper focuses on the dimension, "NOS content…

  16. 75 FR 45133 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2010-08-02

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory.... Institute of Environmental Health Science, P.O. Box 12233, MD EC-30/Room 3170 B, Research Triangle Park, NC... Manpower Development in the Environmental Health Sciences; 93.113, Biological Response to Environmental...

  17. [Regulatory science: modern trends in science and education for pharmaceutical products].

    Science.gov (United States)

    Beregovykh, V V; Piatigorskaia, N V; Aladysheva, Zh I

    2012-01-01

    This article reviews modern trends in development of new instruments, standards and approaches to drugs safety, efficacy and quality assessment in USA and EU that can be called by unique term--"regulatory science" which is a new concept for Russian Federation. New education programs (curricula) developed by USA and EU universities within last 3 years are reviewed. These programs were designed in order to build workforce capable to utilize science approach for drug regulation. The principal mechanisms for financing research in regulatory science used by Food and Drug Administration are analyzed. There are no such science and relevant researches in Russian Federation despite the high demand as well as needs for the system for higher education and life-long learning education of specialists for regulatory affairs (or compliance).

  18. Women and girls in science education: Female teachers' and students' perspectives on gender and science

    Science.gov (United States)

    Crotty, Ann

    Science is a part of all students' education, PreK-12. Preparing students for a more scientifically and technologically complex world requires the best possible education including the deliberate inclusion and full contributions of all students, especially an underrepresented group: females in science. In the United States, as elsewhere in the world, the participation of girls and women in science education and professional careers in science is limited, particularly in the physical sciences (National Academy of Sciences [NAS], 2006). The goal of this research study is to gain a better understanding of the perspectives and perceptions of girls and women, both science educators and students, related to gender and participation in science at the time of an important course: high school chemistry. There is a rich body of research literature in science education that addresses gender studies post---high school, but less research that recognizes the affective voices of practicing female science teachers and students at the high school level (Bianchini, Cavazos, & Helms, 2000; Brown & Gilligan, 1992; Gilligan, 1982). Similarly, little is known with regard to how female students and teachers navigate their educational, personal, and professional experiences in science, or how they overcome impediments that pose limits on their participation in science, particularly the physical sciences. This exploratory study focuses on capturing voices (Brown & Gilligan, 1992; Gilligan, 1982) of high school chemistry students and teachers from selected urban and suburban learning communities in public schools in the Capital Region of New York State. Through surveys, interviews, and focus groups, this qualitative study explores the intersection of the students' and teachers' experiences with regard to the following questions: (1) How do female chemistry teachers view the role gender has played in their professional and personal lives as they have pursued education, degree status, and

  19. Education modifies genetic and environmental influences on BMI

    DEFF Research Database (Denmark)

    Johnson, Wendy; Kyvik, Kirsten Ohm; Skytthe, Axel

    2011-01-01

    environmental correlations between education and BMI differed by level of education, analyzing women and men separately. Correlations between education and BMI were -.13 in women, -.15 in men. High BMI's were less frequent among well-educated participants, generating less variance. In women, this was due...... to restriction of all forms of variance, overall by a factor of about 2. In men, genetic variance did not vary with education, but results for shared and nonshared environmental variance were similar to those for women. The contributions of the shared environment to the correlations between education and BMI......Obesity is more common among the less educated, suggesting education-related environmental triggers. Such triggers may act differently dependent on genetic and environmental predisposition to obesity. In a Danish Twin Registry survey, 21,522 twins of same-sex pairs provided zygosity, height, weight...

  20. Order Theory in Environmental Sciences

    DEFF Research Database (Denmark)

    Sørensen, P. B.; Brüggemann, R.; Lerche, D. B.

    This is the proceeding from the fifth workshop in Order Theory in Environ-mental Science. In this workshop series the concept of Partial Order Theory is development in relation to application and the use is tested based on specific problems. The Partial Order Theory will have a potential use...

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

    Science.gov (United States)

    Ford, D. J.

    2013-12-01

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

  2. A History of Soil Science Education in the United States

    Science.gov (United States)

    Brevik, Eric C.

    2017-04-01

    The formal study of soil science is a fairly recent undertaking in academics. Fields like biology, chemistry, and physics date back hundreds of years, but the scientific study of soils only dates to the late 1800s. Academic programs to train students in soil science are even more recent, with the first such programs only developing in the USA in the early 1900s. Some of the first schools to offer soil science training at the university level included the University of North Carolina (UNC), Earlham College (EC), and Cornell University. The first modern soil science textbook published in the United States was "Soils, Their Properties and Management" by Littleton Lyon, Elmer Fippin and Harry Buckman in 1909. This has evolved over time into the popular modern textbook "The Nature and Properties of Soils", most recently authored by Raymond Weil and Nyle Brady. Over time soil science education moved away from liberal arts schools such as UNC and EC and became associated primarily with land grant universities in their colleges of agriculture. There are currently about 71 colleges and universities in the USA that offer bachelors level soil science degree programs, with 54 of these (76%) being land grant schools. In the 1990s through the early 2000s enrollment in USA soil science programs was on the decline, even as overall enrollment at USA colleges and universities increased. This caused considerable concern in the soil science community. More recently there is evidence that soil science student numbers may be increasing, although additional information on this potential trend is desirable. One challenge soil science faces in the modern USA is finding an academic home, as soils are taught by a wide range of fields and soils classes are taken by students in many fields of study, including soil science, a range of agricultural programs, environmental science, environmental health, engineering, geology, geography, and others.

  3. THE MUSEUM: A PARTNER IN ENVIRONMENTAL EDUC.ATION

    African Journals Online (AJOL)

    . Museum resources are generally underutil ised by educational establishments, not least of all by environmental educators. Some museum activities are explained and ... What is their true mission in society? There are many descriptions of the ...

  4. Medical Sciences Division report for 1993

    Energy Technology Data Exchange (ETDEWEB)

    1993-12-31

    This year`s Medical Sciences Division (MSD) Report is organized to show how programs in our division contribute to the core competencies of Oak Ridge Institute for Science and Education (ORISE). ORISE`s core competencies in education and training, environmental and safety evaluation and analysis, occupational and environmental health, and enabling research support the overall mission of the US Department of Energy (DOE).

  5. Medical Sciences Division report for 1993

    International Nuclear Information System (INIS)

    1993-01-01

    This year's Medical Sciences Division (MSD) Report is organized to show how programs in our division contribute to the core competencies of Oak Ridge Institute for Science and Education (ORISE). ORISE's core competencies in education and training, environmental and safety evaluation and analysis, occupational and environmental health, and enabling research support the overall mission of the US Department of Energy (DOE)

  6. still in an environmental education curriculum research story

    African Journals Online (AJOL)

    The Environmental Education Curriculum Initiative (EECI) in partnership with the .... adoption of an integrated system of lifelong learning ... environmental education in the country and has played .... Environmental Affairs and Tourism, Pretoria.

  7. Levinas and an Ethics for Science Education

    Science.gov (United States)

    Blades, David W.

    2006-01-01

    Despite claims that STS(E) science education promotes ethical responsibility, this approach is not supported by a clear philosophy of ethics. This paper argues that the work of Emmanuel Levinas provides an ethics suitable for an STS(E) science education. His concept of the face of the Other redefines education as learning from the other, rather…

  8. [The effects of an environmental education with newspaper in education (NIE) on the environmental concern and practice].

    Science.gov (United States)

    Sung, Ki-Wol

    2008-12-01

    The purpose of this study was to develop an environmental education program using newspaper articles in education (NIE) and to evaluate changes in concern and practice for environmental protection after NIE. The design was a nonequivalent control group pretest-posttest design. The participants were university students in nursing, of which 31 were assigned to the experimental group and 43 to the control group. The education was carried out for 2 hr, once a week for 7 weeks. Data were analyzed with SPSS WIN 14 program, and included chi2 test, independent t-test, and repeated measure ANOVA. NIE showed significant differences in the changes of attitude toward environment (F=4.461, p=.036). Findings suggest that this NIE in environmental education was effective in changing students' attitudes toward the environment. Therefore this NIE is recommended for inclusion in education for university students in nursing.

  9. Supporting new science teachers in pursuing socially just science education

    Science.gov (United States)

    Ruggirello, Rachel; Flohr, Linda

    2017-10-01

    This forum explores contradictions that arose within the partnership between Teach for America (TFA) and a university teacher education program. TFA is an alternate route teacher preparation program that places individuals into K-12 classrooms in low-income school districts after participating in an intense summer training program and provides them with ongoing support. This forum is a conversation about the challenges we faced as new science teachers in the TFA program and in the Peace Corps program. We both entered the teaching field with science degrees and very little formal education in science education. In these programs we worked in a community very different from the one we had experienced as students. These experiences allow us to address many of the issues that were discussed in the original paper, namely teaching in an unfamiliar community amid challenges that many teachers face in the first few years of teaching. We consider how these challenges may be amplified for teachers who come to teaching through an alternate route and may not have as much pedagogical training as a more traditional teacher education program provides. The forum expands on the ideas presented in the original paper to consider the importance of perspectives on socially just science education. There is often a disconnect between what is taught in teacher education programs and what teachers actually experience in urban classrooms and this can be amplified when the training received through alternate route provides a different framework as well. This forum urges universities and alternate route programs to continue to find ways to authentically partner using practical strategies that bring together the philosophies and goals of all stakeholders in order to better prepare teachers to partner with their students to achieve their science learning goals.

  10. Integrating technology into radiologic science education.

    Science.gov (United States)

    Wertz, Christopher Ira; Hobbs, Dan L; Mickelsen, Wendy

    2014-01-01

    To review the existing literature pertaining to the current learning technologies available in radiologic science education and how to implement those technologies. Only articles from peer-reviewed journals and scholarly reports were used in the research for this review. The material was further restricted to those articles that emphasized using new learning technologies in education, with a focus on radiologic science education. Teaching in higher education is shifting from a traditional classroom-based lecture format to one that incorporates new technologies that allow for more varied and diverse educational models. Radiologic technology educators must adapt traditional education delivery methods to incorporate current technologies. Doing so will help engage the modern student in education in ways in which they are already familiar. As students' learning methods change, so must the methods of educational delivery. The use of new technologies has profound implications for education. If implemented properly, these technologies can be effective tools to help educators.

  11. Increasing participation in the Earth sciences through engagement of K-12 educators in Earth system science analysis, inquiry and problem- based learning and teaching

    Science.gov (United States)

    Burrell, S.

    2012-12-01

    Given low course enrollment in geoscience courses, retention in undergraduate geoscience courses, and granting of BA and advanced degrees in the Earth sciences an effective strategy to increase participation in this field is necessary. In response, as K-12 education is a conduit to college education and the future workforce, Earth science education at the K-12 level was targeted with the development of teacher professional development around Earth system science, inquiry and problem-based learning. An NSF, NOAA and NASA funded effort through the Institute for Global Environmental Strategies led to the development of the Earth System Science Educational Alliance (ESSEA) and dissemination of interdisciplinary Earth science content modules accessible to the public and educators. These modules formed the basis for two teacher workshops, two graduate level courses for in-service teachers and two university course for undergraduate teacher candidates. Data from all three models will be presented with emphasis on the teacher workshop. Essential components of the workshop model include: teaching and modeling Earth system science analysis; teacher development of interdisciplinary, problem-based academic units for implementation in the classroom; teacher collaboration; daily workshop evaluations; classroom observations; follow-up collaborative meetings/think tanks; and the building of an on-line professional community for continued communication and exchange of best practices. Preliminary data indicate increased understanding of Earth system science, proficiency with Earth system science analysis, and renewed interest in innovative delivery of content amongst teachers. Teacher-participants reported increased student engagement in learning with the implementation of problem-based investigations in Earth science and Earth system science thinking in the classroom, however, increased enthusiasm of the teacher acted as a contributing factor. Teacher feedback on open

  12. Engineering and science education for nuclear power

    International Nuclear Information System (INIS)

    1986-01-01

    The Guidebook contains detailed information on curricula which would provide the professional technical education qualifications which have been established for nuclear power programme personnel. The core of the Guidebook consists of model curricula in engineering and science, including relevant practical work. Curricula are provided for specialization, undergraduate, and postgraduate programmes in nuclear-oriented mechanical, chemical, electrical, and electronics engineering, as well as nuclear engineering and radiation health physics. Basic nuclear science and engineering laboratory work is presented together with a list of basic experiments and the nuclear equipment needed to perform them. Useful measures for implementing and improving engineering and science education and training capabilities for nuclear power personnel are presented. Valuable information on the national experiences of IAEA Member States in engineering and science education for nuclear power, as well as examples of such education from various Member States, have been included

  13. Promoting Pre-college Science Education

    Science.gov (United States)

    Lee, R. L.

    1999-11-01

    The Fusion Education Program, with support from DOE, continues to promote pre-college science education for students and teachers using multiple approaches. An important part of our program is direct scientist-student interaction. Our ``Scientist in a Classroom'' program allows students to interact with scientists and engage in plasma science activities in the students' classroom. More than 1000 students from 11 schools have participated in this exciting program. Also, this year more than 800 students and teachers have visited the DIII--D facility and interacted with scientists to cover a broad range of technical and educational issues. Teacher-scientist interaction is imperative in professional development and each year more than 100 teachers attend workshops produced by the fusion education team. We also participate in unique learning opportunities. Members of the team, in collaboration with the San Diego County Office of Education, held a pioneering Internet-based Physics Olympiad for American and Siberian students. Our teamwork with educators helps shape material that is grade appropriate, relevant, and stimulates thinking in educators and students.

  14. 77 FR 33472 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2012-06-06

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory... Health Sciences Special Emphasis Panel International Collaborations in Environmental Health. Date: June....D., Scientific Review Administrator, Nat. Institute of Environmental Health Sciences, Office of...

  15. 78 FR 14562 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2013-03-06

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory... Health Sciences Special Emphasis Panel; Studies on Environmental Health Concerns from Superstorm Sandy... Administrator, National Institute of Environmental Health Sciences, Office of Program Operations, Scientific...

  16. Resonance – Journal of Science Education | News

    Indian Academy of Sciences (India)

    Home; Journals; Resonance – Journal of Science Education. Website Reviews. Articles in Resonance – Journal of Science Education. Volume 4 Issue 8 August 1999 pp 91-93 Website Reviews. Website Review · Harini Nagendra · More Details Fulltext PDF ...

  17. 76 FR 59147 - National Institute of Environmental Health Sciences Notice of Meetings

    Science.gov (United States)

    2011-09-23

    ... Environmental Health Sciences Notice of Meetings Pursuant to section 10(a) of the Federal Advisory Committee Act... Development in the Environmental Health Sciences; 93.113, Biological Response to Environmental Health Hazards... Environmental Research Coordinating Committee. The meetings will be open to the public, with attendance limited...

  18. Online Higher Education Instruction to Foster Critical Thinking When Assessing Environmental Issues - the Brownfield Action Model

    Science.gov (United States)

    Bower, Peter; Liddicoat, Joseph; Dittrick, Diane; Maenza-Gmelch, Terryanne; Kelsey, Ryan

    2013-04-01

    According to the Environmental Protection Agency, there are presently over half a million brownfields in the United States, but this number only includes sites for which an Environmental Site Assessment has been conducted. The actual number of brownfields is certainly into the millions and constitutes one of the major environmental issues confronting all communities today. Taught in part online for more than a decade in environmental science courses at over a dozen colleges, universities, and high schools in the United States, Brownfield Action (BA) is an interactive, web-based simulation that combines scientific expertise, constructivist education philosophy, and multimedia to advance the teaching of environmental science (Bower et al., 2011). In the online simulation and classroom, students form geotechnical consulting companies, conduct environmental site assessment investigations, and work collaboratively to solve a problem in environmental forensics. The BA model contains interdisciplinary scientific and social information that are integrated within a digital learning environment that encourages students to construct their knowledge as they learn by doing. As such, the approach improves the depth and coherence of students understanding of the course material. Like real-world environmental consultants, students are required to develop and apply expertise from a wide range of fields, including environmental science and engineering as well as journalism, medicine, public health, law, civics, economics, and business management. The overall objective is for students to gain an unprecedented appreciation of the complexity, ambiguity, and risk involved in any environmental issue or crisis.

  19. Play with Science in Inquiry Based Science Education

    OpenAIRE

    Andrée, Maria; Lager-Nyqvist, Lotta; Wickman, Per-Olof

    2011-01-01

    In science education students sometimes engage in imaginary science-oriented play where ideas about science and scientists are put to use. Through play, children interpret their experiences, dramatize, give life to and transform what they know into a lived narrative. In this paper we build on the work of Vygotsky on imagination and creativity. Previous research on play in primary and secondary school has focused on play as a method for formal instruction rather than students’ spontaneous info...

  20. Environmental Education through Inquiry and Technology

    Science.gov (United States)

    Markaki, Vassiliki

    2014-01-01

    In the transformative world of today, the role of environmental education has become a much-debated issue. The experience from various EU countries shows lack of a concrete policy for the advancement of those strategic skills that correspond to the identified need for the connection of environmental education to green career choices. This paper…

  1. Opportunities for web-based indicators in environmental sciences.

    Directory of Open Access Journals (Sweden)

    Sergio Malcevschi

    Full Text Available This paper proposes a set of web-based indicators for quantifying and ranking the relevance of terms related to key-issues in Ecology and Sustainability Science. Search engines that operate in different contexts (e.g. global, social, scientific are considered as web information carriers (WICs and are able to analyse; (i relevance on different levels: global web, individual/personal sphere, on-line news, and culture/science; (ii time trends of relevance; (iii relevance of keywords for environmental governance. For the purposes of this study, several indicators and specific indices (relational indices and dynamic indices were applied to a test-set of 24 keywords. Outputs consistently show that traditional study topics in environmental sciences such as water and air have remained the most quantitatively relevant keywords, while interest in systemic issues (i.e. ecosystem and landscape has grown over the last 20 years. Nowadays, the relevance of new concepts such as resilience and ecosystem services is increasing, but the actual ability of these concepts to influence environmental governance needs to be further studied and understood. The proposed approach, which is based on intuitive and easily replicable procedures, can support the decision-making processes related to environmental governance.

  2. Environmental protection belongs to the public: A vision for citizen science at EPA

    Science.gov (United States)

    Parker, A.; Dosemagen, S.

    2017-12-01

    As a collaborative and open approach to science, citizen science has the potential make science more actionable, applicable, and usable, especially when designed with scientists, communities and decision-makers as partners. In response to recent interest in citizen science from the US Environmental Protection Agency, the National Advisory Council for Environmental Policy and Technology provided EPA with advice and recommendations on how to integrate citizen science into the core work of EPA. The Council's 28 members—representatives of academia; business and industry; nongovernmental organizations; and state, local and tribal governments—identifies citizen science as an invaluable opportunity for EPA to strengthen public support for EPA's mission and the best approach for the Agency to connect with the public on environmental protection. The report recommends that EPA embrace citizen science as a core tenet of environmental protection, invest in citizen science for communities, partners, and the Agency, enable the use of citizen science data at the Agency, integrate citizen science into the full range of work of EPA. This presentation will outline principles and strategy for integrating citizen science into science and policy at the national level, increasing the usability of citizen science data for decision-making and policy, and leveraging citizen science for environmental protection.

  3. Environmental engineering education: examples of accreditation and quality assurance

    Science.gov (United States)

    Caporali, E.; Catelani, M.; Manfrida, G.; Valdiserri, J.

    2013-12-01

    particular, the accreditation models of the multidisciplinary first cycle degree in Civil, Building and Environmental Engineering and the more specific second cycle degree in Environmental Engineering are discussed. The critical issues to assure the quality and the status of environmental engineering graduates, in terms of applying knowledge capacities and technical innovative competences, according to the more engineering focused EUR-ACE skill descriptors as well as with respect to the Dublin descriptors, at local and global scale are also compared. The involvement of the professional working world in the definition of goals in skills, of typical expectations of achievements and abilities is also described. The system for educating engineers in communicating knowledge and understanding, making informed judgments and choices, capacities to lifelong learning is in addition assessed. The promotion of innovative aspects related with the environmental engineering education, and of the role that science and technology could play in environmental engineering education is also taken into consideration.

  4. 76 FR 5184 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2011-01-28

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory... Health Sciences Special Emphasis Panel; Outstanding New Environmental Scientist Award. Date: February 24... Environmental Health Sciences, Building 101, Rodbell Auditorium, 111 T. W. Alexander Drive, Research Triangle...

  5. 77 FR 61771 - National Institute of Environmental Health Sciences; Notice of Closed Meetings

    Science.gov (United States)

    2012-10-11

    ... Environmental Health Sciences; Notice of Closed Meetings Pursuant to section 10(d) of the Federal Advisory... clearly unwarranted invasion of personal privacy. Name of Committee: Environmental Health Sciences Review... applications. Place: National Institute of Environmental Health Sciences, Building 101, Rodbell Auditorium, 111...

  6. 76 FR 11500 - National Institute of Environmental Health Sciences; Notice of Closed Meetings

    Science.gov (United States)

    2011-03-02

    ... Environmental Health Sciences; Notice of Closed Meetings Pursuant to section 10(d) of the Federal Advisory... Administrator, Nat. Institute of Environmental Health Sciences, Office of Program Operations, Scientific Review... . Name of Committee: National Institute of Environmental Health Sciences Special Emphasis Panel; Novel...

  7. Finding Meaningful Roles for Scientists in science Education Reform

    Science.gov (United States)

    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.

  8. Resonance – Journal of Science Education | Indian Academy of ...

    Indian Academy of Sciences (India)

    Home; Journals; Resonance – Journal of Science Education. R K Varma. Articles written in Resonance – Journal of Science Education. Volume 3 Issue 8 August 1998 pp 8-13. On Science Education and Scientific Research · R K Varma · More Details Fulltext PDF ...

  9. Multicultural education, pragmatism, and the goals of science teaching

    Science.gov (United States)

    El-Hani, Charbel Niño; Mortimer, Eduardo Fleury

    2007-07-01

    In this paper, we offer an intermediate position in the multiculturalism/universalism debate, drawing upon Cobern and Loving's epistemological pluralism, pragmatist philosophies, Southerland's defense of instructional multicultural science education, and the conceptual profile model. An important element in this position is the proposal that understanding is the proper goal of science education. Our commitment to this proposal is explained in terms of a defense of an ethics of coexistence for dealing with cultural differences, according to which social argumentative processes—including those in science education—should be marked by dialogue and confrontation of arguments in the search of possible solutions, and an effort to (co-)live with differences if a negotiated solution is not reached. To understand the discourses at stake is, in our view, a key requirement for the coexistence of arguments and discourses, and the science classroom is the privileged space for promoting an understanding of the scientific discourse in particular. We argue for "inclusion" of students' culturally grounded ideas in science education, but in a sense that avoids curricular multicultural science education, and, thus, any attempt to broaden the definition of "science" so that ideas from other ways of knowing might be simply treated as science contents. Science teachers should always take in due account the diversity of students' worldviews, giving them room in argumentative processes in science classrooms, but should never lose from sight the necessity of stimulating students to understand scientific ideas. This view is grounded on a distinction between the goals of science education and the nature of science instruction, and demands a discussion about how learning is to take place in culturally sensitive science education, and about communicative approaches that might be more productive in science classrooms organized as we propose here. We employ the conceptual profile model to

  10. Investing in citizen science can improve natural resource management and environmental protection

    Science.gov (United States)

    McKinley, Duncan C.; Miller-Rushing, Abraham J.; Ballard, Heidi L.; Bonney, Rick; Brown, Hutch; Evans, Daniel M.; French, Rebecca A.; Parrish, Julia K.; Phillips, Tina B.; Ryan, Sean F.; Shanley, Lea A.; Shirk, Jennifer L.; Stepenuck, Kristine F.; Weltzin, Jake F.; Wiggins, Andrea; Boyle, Owen D.; Briggs, Russell D.; Chapin, Stuart F.; Hewitt, David A.; Preuss, Peter W.; Soukup, Michael A.

    2015-01-01

    Citizen science has made substantive contributions to science for hundreds of years. More recently, it has contributed to many articles in peer-reviewed scientific journals and has influenced natural resource management and environmental protection decisions and policies across the nation. Over the last 10 years, citizen science—participation by the public in a scientific project—has seen explosive growth in the United States, particularly in ecology, the environmental sciences, and related fields of inquiry. In this report, we explore the current use of citizen science in natural resource and environmental science and decision making in the United States and describe the investments organizations might make to benefit from citizen science.

  11. Simulations as Scaffolds in Science Education

    DEFF Research Database (Denmark)

    Renken, Maggie; Peffer, Melanie; Otrel-Cass, Kathrin

    This book outlines key issues for addressing the grand challenges posed to educators, developers, and researchers interested in the intersection of simulations and science education. To achieve this, the authors explore the use of computer simulations as instructional scaffolds that provide...... strategies and support when students are faced with the need to acquire new skills or knowledge. The monograph aims to provide insight into what research has reported on navigating the complex process of inquiry- and problem-based science education and whether computer simulations as instructional scaffolds...

  12. Taming Typhon: Advancing Climate Literacy by Coordinating Federal Earth System Science Education Investments Through the U.S. Climate Change Science Program

    Science.gov (United States)

    Karsten, J. L.; Niepold, F.; Wei, M.; Waple, A. M.

    2008-12-01

    Thirteen Federal agencies in the United States invest in research, communication, and education activities related to climate and global change. The U.S. Climate Change Science Program (CCSP) works to integrate the research activities of these different agencies, with oversight from the Office of Science and Technology Policy, the Council on Environmental Quality, the National Economic Council and the Office of Management and Budget. The CCSP is the result of a Presidential initative in 2001 to build on the Global Change Research Program, which exists as a result of the Global Change Research Act of 1990. This initiative was to shift the focus of the Program from 'discovery and characterization' to 'differentiation and strategy investigation.' With this shift, CCSP's focus is now on evaluating optimal strategies for addressing climate change risks, improving coordination among the Federal agencies, communicating research results to all stakeholders (including national policy leaders and local resource managers), and improving public debate and decision-making related to global change. Implicit to these activities is the need to educate the general public about the science of climate change and its consequences, as well as coordinate Federal investments related to climate change education. This is no small task, given the variety of missions and approaches of the participating agencies. Recognizing that its Communications Interagency Working Group (CIWG) does not have the expertise or focus to adequately address issues related to science education, the CCSP recently established an ad-hoc Education Interagency Working Group (EIWG), comprising representatives from all 13 agencies, that will work closely with the CIWG to enhance education goals. Its mission is to advance literacy in climate and related sciences and increase informed decision making for the Nation. The EIWG envisions that its primary activities in the near-term will be focused on establishing: (1) a

  13. Growth of Environmental Science at the NSLS

    International Nuclear Information System (INIS)

    Northrup, P.; Lanzirotti, A.; Celestian, A.

    2007-01-01

    In the 25 years since the National Synchrotron Light Source (NSLS) began operations, synchrotron 'user facilities' have had a growing impact on research in molecular environmental science (MES). For example, synchrotron-based analytical techniques have allowed researchers to determine the molecular-level speciation of environmentally relevant elements and evaluate their spatial distribution and phase association at very low concentration levels (low parts per million) with micrometer or nanometer resolution [1]. For the environmental scientist, one of the primary advantages of these synchrotron-based techniques is that samples need not be disturbed or destroyed for study; characterization can often be done in-situ in dilute and heterogeneous natural samples with no need for species separation, pre-concentration, or pre-treatment [2]. Liquids, hydrated solids, and biological samples can also often be directly analyzed, which is of fundamental importance in environmental science for understanding the molecular-scale processes that occur at mineral-water interfaces and in understanding how abiotic and biotic processes are involved in the distribution, mobility and ultimate fate of molecular species in the environment.

  14. Growth of Environmental Science at the NSLS

    Energy Technology Data Exchange (ETDEWEB)

    Northrup,P.; Lanzirotti, A.; Celestian, A.

    2007-01-01

    In the 25 years since the National Synchrotron Light Source (NSLS) began operations, synchrotron 'user facilities' have had a growing impact on research in molecular environmental science (MES). For example, synchrotron-based analytical techniques have allowed researchers to determine the molecular-level speciation of environmentally relevant elements and evaluate their spatial distribution and phase association at very low concentration levels (low parts per million) with micrometer or nanometer resolution [1]. For the environmental scientist, one of the primary advantages of these synchrotron-based techniques is that samples need not be disturbed or destroyed for study; characterization can often be done in-situ in dilute and heterogeneous natural samples with no need for species separation, pre-concentration, or pre-treatment [2]. Liquids, hydrated solids, and biological samples can also often be directly analyzed, which is of fundamental importance in environmental science for understanding the molecular-scale processes that occur at mineral-water interfaces and in understanding how abiotic and biotic processes are involved in the distribution, mobility and ultimate fate of molecular species in the environment.

  15. Time for action: science education for an alternative future

    Science.gov (United States)

    Hodson, Derek

    2003-06-01

    Following a brief historical survey of the popular 'slogans' that have influenced science education during the past quarter century and a review of current international debate on scientific literacy and science pedagogy, the author takes the view that while much of value has been achieved, there is still considerable cause for concern and that it is time for action in two senses. First, it is time to take action on the school science curriculum because it no longer meets the needs, interests and aspirations of young citizens. Second, it is time for a science curriculum oriented toward sociopolitical action. The author argues that if current social and environmental problems are to be solved, we need a generation of scientifically and politically literate citizens who are not content with the role of 'armchair critic'. A particular concern in North America is the link between science education, economic globalization, increasing production and unlimited expansion - a link that threatens the freedom of individuals, the spiritual well-being of particular societies and the very future of the planet. The author's response is to advocate a politicized, issues-based curriculum focused on seven areas of concern (human health; food and agriculture; land, water and mineral resources; energy resources and consumption; industry; information transfer and transportation; ethics and social responsibility) and addressed at four levels of sophistication, culminating in preparation for sociopolitical action. The curriculum proposal outlined in the article is intended to produce activists: people who will fight for what is right, good and just; people who will work to re-fashion society along more socially-just lines; people who will work vigorously in the best interests of the biosphere. At the heart of this curriculum is a commitment to pursue a fundamental realignment of the values underpinning Western industrialized society. Achieving that goal is a formidable task - one that

  16. 78 FR 25754 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2013-05-02

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory... of Extramural Research and Training, Nat. Institute of Environmental Health Science, P.O. Box 12233... Health Sciences; 93.113, Biological Response to Environmental Health Hazards; 93.114, Applied...

  17. 76 FR 52672 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2011-08-23

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory.... of Environmental Health Sciences, Keystone Building, 530 Davis Drive, Research Triangle Park, NC..., Division of Extramural Research and Training, Nat. Institute of Environmental Health Sciences, P.O. Box...

  18. 78 FR 39739 - National Institute of Environmental Health Sciences; Notice of Closed Meeting

    Science.gov (United States)

    2013-07-02

    ... Environmental Health Sciences; Notice of Closed Meeting Pursuant to section 10(d) of the Federal Advisory... clearly unwarranted invasion of personal privacy. Name of Committee: Environmental Health Sciences Review... Research and Training, National Institute of Environmental Health Sciences, P.O. Box 12233, MD EC-30...

  19. 78 FR 14312 - National Institute of Environmental Health Sciences; Notice of Closed Meetings

    Science.gov (United States)

    2013-03-05

    ... Environmental Health Sciences; Notice of Closed Meetings Pursuant to section 10(d) of the Federal Advisory... Health Sciences Special Emphasis Panel; Understanding Environmental Control of Epigenetic/Mechanisms... Extramural Research and Training, Nat. Institute of Environmental Health Sciences, P.O. Box 12233, MD EC-30...

  20. 75 FR 61765 - National Institute of Environmental Health Sciences; Notice of Closed Meetings

    Science.gov (United States)

    2010-10-06

    ... Environmental Health Sciences; Notice of Closed Meetings Pursuant to section 10(d) of the Federal Advisory... Environmental Health Sciences Special Emphasis Panel, Superfund Research and Training Program. Date: October 26...-Tilotta, PhD, Scientific Review Officer, Nat. Institute of Environmental Health Sciences, Office of...