The excitement of astrophysical research and discovery is brought into the high school science and mathematics classes through a flexible set of student activities and projects on variable stars. The project includes a computerized database, of 400,000 measurements of brightness of 150 variable stars in five constellations over 25 years, from which students can deduce properties, processes, and evolution of these stars. Students can make additional measurements and discoveries from carefully selected time sequences of 125 35mm slides or from actual measurements from the night sky. A comprehensive student manual and instructional videos make the materials self-contained and easy to use. The teacher manual enables the instructor to adapt the materials to skills, objectives and local curricula. The material can be used in a variety of contexts: traditional mathematics and science classes at both the high school and college level, independent projects, summer institutes, and community science clubs. The material will be field tested in classes and refined through workshops with teachers. A newsletter and a video about amateur astronomers is planned.
The Maryland Science Center has received a SEPA grant to develop an exhibition, intern program and web site focusing on cell biology and stem cell research. The working title of the exhibition is Cellular Universe. The exhibit is intended to serve the following audiences: Families with children age nine and older; School groups (grades four and up); Adults; 9th grade underserved high school students in three local schools and/or community centers. Topics the exhibit will treat include: Structure and function of cells; Stem cells and their potential, the controversy surrounding stem cell
The Earth & Sky radio series reaches over 2.8 million individuals in the United States each week. This grant, which will diminish each year over a four-year period, will enable the project to accomplish the following goals: * Continue production and distribution of the Earth & Sky radio series * Distribute a bi-annual booklet for teachers, Earth In the Classroom * Establish a partnership between the Earth & Sky Young Producers Contest and National Science and Technology Week. * Increase the visual content of Earth & Sky Online * Launch an * Earth & Sky Classroom Project to provide teachers and students with a guided "Internet Experience" simulated on a CD and, therefore, not requiring an Internet connection. * Produce and test a 156 segment "trial run" of a Kids' Earth & Sky radio series designed for the emerging Radio Disney network. Earth & Sky is produced and hosted by Deborah Byrd and Joel Block. They work with a team of producer/writers and interact on a regular basis with members of a team of over 90 science advisors.
The scientific community is challenged by the need to reach out to students who have traditionally not been attracted to engineering and the sciences. This project would provide a link between the University of Michigan and the teachers and students of secondary education in the State of Michigan with an initial emphasis on southeast Michigan, through the creation of a range of computer services which will provide interactive access to current weather and climate change information. Taking advantage of a unique computer network capacity within the State of Michigan named MichNet which provides local phone ports in virtually every major city in the state, and the resources available to the university community via the University Corporation for Atmospheric Research (UCAR) UNIDATA program, this project would provide secondary schools with access to a state-of-the-art interactive weather information system. The real-time data available via the system, supplemented by interactive computer modules designed in collaboration with earth science teachers, will provide animated background information on a range of climate and weather related topics. While the principal objective of this project will be to provide educationally stimulating interactive computer systems and electronic weather and climate modules for application in inner city Detroit and its environs, the unique nature of the available computer networking will allow virtually every school system in the state to have access. Subsequently successful completion of this project could eventually make the same systems available to other cities and states.
As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program funds innovative resources for use in a variety of settings. This project is a time sensitive educational response to the 7.8 magnitude earthquake that struck Nepal on April 25, 2015 and was followed by major aftershocks. This project builds on the intense worldwide interest in that disaster by developing and distributing media resources for the public and educators explaining the scientific research into tectonic and fluvial processes of this highly vulnerable region encompassing the Himalayas of Nepal, the Ganges-Brahmaputra River Delta of Bangladesh and India, and the mountains of northeastern India. Project deliverables include PBS NewsHour broadcasts and online stories, short videos for classroom use, 3D/2D videos for public screenings in museums, Earth Magazine blogs and articles, and DVDs. Making new research understandable and accessible to the public is an important activity of the U.S. research enterprise. NSF is making a substantial investment in earth sciences research to increase knowledge of the conditions and processes that periodically cause earthquakes, landslides, and flooding. This education project leverages those investments and the public interest in the recent Nepal earthquake with a major public engagement opportunity that has the potential for reaching millions of students, teachers, and the public both in the U.S. and in other vulnerable regions.
The Next Generation Science Standards (NGSS) identify an ambitious progression for learning energy, beginning in elementary school. To help the nation's teachers address this challenge, this project will develop and investigate the opportunities and limitations of Focus on Energy, a professional development (PD) system for elementary teachers (grades 3-5). The PD will contain: resources that will help teachers to interpret, evaluate and cultivate students' ideas about energy; classroom activities to help them to identify, track and represent energy forms and flows; and supports to help them in engaging students in these activities. Teachers will receive the science and pedagogical content knowledge they need to teach about energy in a crosscutting way across all their science curricula; students will be intellectually engaged in the practice of developing, testing, and revising a model of energy they can use to describe phenomena both in school and in their everyday lives; and formative assessment will guide the moment-by-moment advancement of students' ideas about energy. This project will develop and test a scalable model of PD that will enhance the ability of in-service early elementary teachers to help students learn energy concepts by coordinating formative assessment, face-to-face and web-based PD activities. Researchers will develop and iteratively refine tools to assess both teacher and student energy reasoning strategies. The goals of the project include (1) teachers' increased facility with, and disciplined application of, representations and energy reasoning to make sense of everyday phenomena in terms of energy; (2) teachers' increased ability to interpret student representations and ideas about energy to make instructional decisions; and (3) students' improved use of representations and energy reasoning to develop and refine models that describe energy forms and flows associated with everyday phenomena. The web-based product will contain: a set of formative assessments to help teachers to interpret student ideas about energy based on the Facets model; a series of classroom tested activities to introduce the Energy Tracking Lens (method to explore energy concept using multiple representations); and videos of classroom exemplars as well as scientists thinking out loud while using the Energy Tracking Lens. The project will refine the existing PD and build a system that supports online implementation by constructing a facilitator's guide so that the online community can run with one facilitator.
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TEAM MEMBERS:
Sara LacyRoger TobinNathaniel BrownStamatis VokosRachel ScherrKara GrayLane SeeleyAmy Robertson
The Internet, specifically the World Wide Web (WWW), has the potential to deliver science education materials directly to classrooms, media centers, libraries and homes. The current application seeks to use this new technology through a collaborative effort of an active scientist and a group of middle school science teachers to develop, disseminate and evaluate educational materials related to neuroscience for use in middle school science classes. This project attempts to introduce new technologies into the science classroom, extend science education to include the information superhighway and increase parental involvement in their children's education. Materials will be integrated with the existing middle school science curriculum and will include l) on-line and off-line experiments and activities covering a range of topics in neuroscience, 2) a "virtal neuroscience laboratory", 3) an Internet neuroscience resource list and 4) a "Neuroscientist Network" consisting of active neuroscientists around the world who will serve as experts answering student questions. All activities will be designed will attention to being self-paced, hands-on, entertaining and to involve Cooperative learning. Both quantitative and qualitative methods will be used to evaluate the usage of the Intemet Neuroscience Resource. It is hoped that this project will serve as a model to other scientists and teachers and to encourage them to develop Internet resources in their own areas of expertise for use in the classroom.
This project will disseminate neuroscience materials to secondary school science teachers via a CD-ROM. These materials will be evaluated to 1) determine changes in student attitudes toward science; 2) to assess changes in student knowledge of neuroscience concepts and 3) to quantify how students and teachers are using the Internet Neuroscience Resource ("Neuroscience for Kids"). The Scientific Attitude Inventory-II will be used to evaluate middle school student attitudes toward science before and after exposure to the Neuroscience Resource. Pretesting and posttesting of middle school students will be performed to evaluate content knowledge of neuroscience-related concepts and principles. Questions that comprise the content evaluation inventory will be based on the guidelines and benchmarks established by the American Association for the Advancement of Science, the National Research Council, and the National Science Teachers Association. Prior to general distribution, pretests and posttests for both attitude and content knowledge will be evaluated for validity and reliability with pilot group of middle school students. An Internet version of the Neuroscience Resource will continue to be developed.
The long-term goal is to broaden our model program that currently targets African-American populations in the national capital area. The aim of the program is to: a) educate junior and senior high students and elementary school teachers directly; and b) provide opportunities for exploration of health-related sciences for the public at large (via an interactive website) so that topics in the biomedical sciences become "friendly and familiar" rather than the existing stereotype that science is erudite, obtuse, and incomprehensible. Specific objectives: (A) Design hands-on experiences in science laboratories and opportunities to interact with scientists in the setting of a sophisticated research institute; especially target under-represented minorities, students from inner city schools and other local schools where science opportunities may be limited. This will include junior and high school students, elementary school teachers, as well as interactions with Children's Museum and other similar organizations. (B) Set up interactive web-based informatics to include: i) a system where high school students could refine the question they are posing for science projects by discussing it with a professional scientist; ii) a general "ask-the-expert" site for science and health issues; iii) a reference site containing the detailed experimental protocols for student experiments; and iv) an interactive resource to aid teachers throughout the U.S. to establish contacts with scientists. The goal of this project is to extend the reach of current health science programs that are targeted to females, African-American junior and senior high school students, and elementary school teachers, located in the Washington, D.C., metropolitan area. The project includes laboratory apprenticeships, student mentoring, and an interactive website to help students and teachers establish contact with scientists nationwide.
Mobile technology can be used to scaffold inquiry-based learning, enabling learners to work across settings and times, singly or in collaborative groups. It can expand learners’ opportunities to understand the nature of inquiry whilst they engage with the scientific content of a specific inquiry. This Sharples et al. paper reports on the use of the mobile computer-based inquiry toolkit nQuire. Teachers found the tool useful in helping students to make sense of data from varied settings.
This volume explores how technology-supported learning environments can incorporate physical activity and interactive experiences in formal and informal education. It presents cutting-edge research and design work on a new generation of "body-centric" technologies such as wearable body sensors, GPS tracking devices, interactive display surfaces, video game controller devices, and humanlike avatars. Contributors discuss how and why each of these technologies can be used in service of learning within K-12 classrooms and at home, in museums and online. Citing examples of empirical evidence and
The digital revolution has transformed how young people discover and pursue their interests; how they communicate with and learn from other people; and how they encounter and learn about the world around them. How can we identify best practices for incorporating new media technologies into learning environments in a way that resonates with youth, including their interests, goals, and the ways they use technology in their everyday lives? How do we resolve the need to document and recognize informal STEM learning and connect it to formal education contexts? What strategies can be developed for inspiring and tracking student progress towards the learning goals outlined in the Next Generation Science Standards (NGSS)? These questions are the underlying motivation for this CAREER program of research. Digital badges represent a specific kind of networked technology and have been touted as an alternative credentialing system for recognizing and rewarding learning across domains, both inside and outside of formal education contexts. While there is considerable enthusiasm and speculation around the use of digital badges, the extent to which they succeed at empowering learners and connecting their learning across contexts remains largely untested. This project seeks to fill this gap in knowledge. The approach taken for this program of study is a three phased design-based research effort that will be focused on four objectives: (1) identifying design principles and support structures needed to develop and implement a digital badge system that recognizes informal STEM learning; (2) documenting the opportunities and challenges associated with building a digital badge ecosystem that connects informal learning contexts to formal education and employment opportunities; (3) determining whether and how digital badges support learners' STEM identities; and (4) determining whether and how digital badges help learners to connect their informal STEM learning to formal education and employment opportunities. In Phase 1, an existing prototype created in prior work at Seattle's Pacific Science Center will be developed into a fully functional digital badge system. In Phase 2, the PI will also work collaboratively with higher education stakeholders to establish formal mechanisms for recognizing Pacific Science Center badges in higher education contexts. In Phase 3, the badge ecosystem will be expanded and students' use of and engagement with badges will be tracked as they apply to and enter college. The project involves high school students participating in the Discovery Corps program at the Pacific Science Center, undergraduate and graduate students at the University of Washington, and stakeholders in the K-12 and higher education community in Seattle. Educational activities integrated with this program of research will support: (1) mentoring University of Washington students throughout the project to develop their skills as practice-oriented researchers; (2) incorporating the research processes and findings from the project into university courses aimed at developing students' understanding of the opportunities and challenges associated with using new media technologies to support learning; and (3) using the research findings to develop educational outreach initiatives to support other informal STEM learning institutions in their use of digital badges.