The Coalition for Science After School (CSAS) was established in 2004 in response to the growing need for more STEM (science, technology, engineering, and mathematics) learning opportunities in out-of-school time. CSAS sought to build this field by uniting STEM education goals with out-of-school time opportunities and a focus on youth development. Over a decade of work, CSAS Steering Committee members, staff and partners advocated for STEM in out-of-school-time settings, convened leaders, and created resources to support this work. CSAS leadership decided to conclude CSAS operations in 2014, as the STEM in out-of-school time movement had experienced tremendous growth of programming and attention to science-related out-of-school time opportunities on a national level. In its ten-year strategic plan, CSAS took as its vision the full integration of the STEM education and out-of-school time communities to ensure that quality out-of-school time STEM opportunities became prevalent and available to learners nationwide. Key CSAS activities included: (1) Setting and advancing a collective agenda by working with members to identify gaps in the field, organizing others to create solutions that meet the needs, identifying policy needs in the field and supporting advocates to advance them; (2) Developing and linking committed communities by providing opportunities for focused networking and learning through conferences, webinars, and other outreach activities; and (3) Identifying, collecting, capturing, and sharing information and available research and resources in the field. The leadership of the Coalition for Science After School is deeply grateful to the funders, partners, supporters, and constituents that worked together to advance STEM in out-of-school time during the last decade, and that make up today's rich and varied STEM in out-of-school time landscape. We have much to be proud of, but as a movement there is much more work to be done. As this work continues to expand and deepen, it is appropriate for the Coalition for Science After School to step down as the many other organizations that have emerged over the last decade take on leadership for the critical work that remains to be done. A timeline and summary of CSAS activities, products, and accomplishments is available for download on this page. All resources noted in the narrative are also available for download below.
Students will apply themselves to learning if the context interests them. Focusing on a subject close to middle school students' hearts, such as fashion, rather than on specific academic tasks such as writing or researching, builds intrinsic motivation for learning. This article explores the Fabulous Fashions program, which engages students in mathematics and literacy through the context of their interest in fashion.
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Anne Thompson
resourceprojectProfessional Development, Conferences, and Networks
This model science teacher retention and mentoring project will involve more than 300 elementary teachers in "Lesson Study" of inquiry science around school gardens. Drawing on the rich resources of the University of California Botanical Garden and the science educators at the Lawrence Hall of Science this project will develop Teacher Leaders and provide science content professional development to colleagues in four urban school districts. Using the rich and authentic contexts of gardens to engage students and teachers in scientific inquiry opens the opportunity to invite parents to become actively involved with their children in the learning process. As teachers improve their classroom practices of teaching science through inquiry with the help of school-based mentoring they are able to connect the teaching of science to mathematics and literacy and will be able to apply the lesson study approach in their teaching of other innovative projects. Teacher leaders and mentors will have on-going learning opportunities as well as engage participating teachers in lesson study and reflection aimed toward improving science content understanding and the quality of science learning in summer garden learning experiences and having context rich science inquiry experiences throughout the school year.
This collaborative project aims to establish a national computational resource to move the research community much closer to the realization of the goal of the Tree of Life initiative, namely, to reconstruct the evolutionary history of all organisms. This goal is the computational Grand Challenge of evolutionary biology. Current methods are limited to problems several orders of magnitude smaller, and they fail to provide sufficient accuracy at the high end of their range. The planned resource will be designed as an incubator to promote the development of new ideas for this enormously challenging computational task; it will create a forum for experimentalists, computational biologists, and computer scientists to share data, compare methods, and analyze results, thereby speeding up tool development while also sustaining current biological research projects. The resource will be composed of a large computational platform, a collection of interoperable high-performance software for phylogenetic analysis, and a large database of datasets, both real and simulated, and their analyses; it will be accessible through any Web browser by developers, researchers, and educators. The software, freely available in source form, will be usable on scales varying from laptops to high-performance, Grid-enabled, compute engines such as this project's platform, and will be packaged to be compatible with current popular tools. In order to build this resource, this collaborative project will support research programs in phyloinformatics (databases to store multilevel data with detailed annotations and to support complex, tree-oriented queries), in optimization algorithms, Bayesian inference, and symbolic manipulation for phylogeny reconstruction, and in simulation of branching evolution at the genomic level, all within the context of a virtual collaborative center. Biology, and phylogeny in particular, have been almost completely redefined by modern information technology, both in terms of data acquisition and in terms of analysis. Phylogeneticists have formulated specific models and questions that can now be addressed using recent advances in database technology and optimization algorithms. The time is thus exactly right for a close collaboration of biologists and computer scientists to address the IT issues in phylogenetics, many of which call for novel approaches, due to a combination of combinatorial difficulty and overall scale. The project research team includes computer scientists working in databases, algorithm design, algorithm engineering, and high-performance computing, evolutionary biologists and systematists, bioinformaticians, and biostatisticians, with a history of successful collaboration and a record of fundamental contributions, to provide the required breadth and depth. This project will bring together researchers from many areas and foster new types of collaborations and new styles of research in computational biology; moreover, the interaction of algorithms, databases, modeling, and biology will give new impetus and new directions in each area. It will help create the computational infrastructure that the research community will use over the next decades, as more whole genomes are sequenced and enough data are collected to attempt the inference of the Tree of Life. The project will help evolutionary biologists understand the mechanisms of evolution, the relationships among evolution, structure, and function of biomolecules, and a host of other research problems in biology, eventually leading to major progress in ecology, pharmaceutics, forensics, and security. The project will publicize evolution, genomics, and bioinformatics through informal education programs at museum partners of the collaborating institutions. It also will motivate high-school students and college undergraduates to pursue careers in bioinformatics. The project provides an extraordinary opportunity to train students, both undergraduate and graduate, as well as postdoctoral researchers, in one of the most exciting interdisciplinary areas in science. The collaborating institutions serve a large number of underrepresented groups and are committed to increasing their participation in research.
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Tandy WarnowDavid HillisLauren MeyersDaniel MirankerWarren Hunt, Jr.
Learning to Work with the Public in the Context of Local Systemic Change is a five-year Teacher Enhancement initiative to build a knowledge base and develop the necessary tools and resources for teachers and administrators to engage with their parents and public in pursuit of quality mathematics, and to prepare teacher leaders and administrators to successfully lead these efforts in their schools. The project has three major components: (1) focused and sustained work with teachers, administrators, school boards, parents and the public in strategically located current and potential NSF-supported Local Systemic Change communities; (2) the development and implementation of mathematics sessions and materials designed for parents/public and informed by the project's research/findings, and the preparation of teacher leaders and administrators to conduct these sessions within their own communities; and (3) dissemination conferences and other outreach activities. More specifically, the project will (a) engage in studies that identify the elements critical for successful intervention with parents and the public, (b) develop materials that can be used by lead teachers and other educational leaders to work with peer teachers and the broader public in their home communities, and (c) provide the professional development necessary to support implementation. The plan of work for the project is designed around the following questions: (1) What does it take to secure a public that is knowledgeable of issues in mathematics education and knowledgeable of what it means to teach important and relevant mathematics for understanding? (2) Will a knowledgeable public support and/or actively advocate for mathematics reform? If so, what is the nature of their advocacy? (3) What impact will a knowledgeable and/or proactive public have on the efforts of current and potential Local Systemic Change (LSC) projects to improve the quality of mathematics instruction in schools? (4) Are there critical times during mathematics restructuring efforts when parent engagement is essential? If so, what are those times and what is the nature of support needed? (5) What are the critical issues and caveats that need to be considered in designing and delivering successful mathematics education sessions for parents and the public? (6) What kinds of public engagement can best be accomplished by teacher leaders working within their own communities? What kinds of support do local leaders need in order to work successfully with parents and the public? (7) What kinds of public engagement can best be accomplished by national mathematics education leaders who come into a community on a limited basis? The work to be performed in the project is a carefully designed effort to develop a more practice-based understanding of the critical elements needed for productive public involvement in support of quality mathematics. Sites participating in the plan of work are Portland (OR), St. Vrain (CO), and San Francisco (CA). Resources and tools (e.g., deliverables) planned include professional development materials that can be used by teacher leaders and administrators as they work with peer teachers, as well as with parents and the public; rough-cut video tapes that are potentially useful in these professional development sessions; and a website. Cost sharing is derived from participating school districts and the Exxon and Intel Foundations.
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Ruth ParkerJaneane GolliherDominic PeressiniLisa Adajian
The Museum of Science in Boston will develop exhibits and programs for visitors to use models as tools for understanding the world around them. It is the 4th stage of a six-part, long-range vision and plan that focuses on comprehending science as a way of thinking and doing. "Making Models" will serve over one million visitors per year, mostly families and school groups. The models to be featured include physical, biological, conceptual, mathematical, and computer simulation models. Four (4) specific science inquiry skills will be stressed, which are associated with making and using models: recognition of similarities, assessment of limitations, communication of ideas, and the creation of one's own models for developing personal understanding and appreciation of the world in which we live. In tandem with this new exhibit, some current exhibits and programs will be modified to meet these modeling goals. Demonstrating the application of these new exhibit techniques for other museums and science centers, and evaluating how visitors learn in this setting will also be performed, with the results disseminated on a national level. The Museum will collaborate with two (2) other nationally known sites in this development and evaluation of exhibit components, creation of new teacher development programs, and the development of models-related web resources.
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Douglas SmithLarry BellPaul Fontiane
The Education Development Center, Incorporated, requests $2,081,018 to create informal learning opportunities in science, mathematics, engineering and technology utilizing the study of the ancient African civilization of Nubia as context. Educational activities and resources will be developed based on the extensive ongoing archeological research on historical Nubia. The two main components of the project are a traveling exhibit with related educational materials and a website that will provide the target audience an opportunity to access extensive on-line resources and activities. The project will provide community outreach and professional development for educators in museums, community groups, schools and libraries. The project is designed for thirty-six months' duration. In year one, a network of collaborators in the Boston area will focus on research and development; in year two, project materials will be piloted and evaluated in six cities, and on-line professional development programs will be conducted; and in year three, project materials will be disseminated directly to 60 sites and more broadly via the internet.
Mixing in Math is a multi-dimensional, three-year project that seeks to build the capacity of after-school programs to provide meaningful and engaging math activities for youth. Program collaborators including project leaders from TERC and after-school program leaders will reach approximately 40,000 children through at least 350 sites and approximately 9,000 staff and volunteers. Drawing on the unique features of the after-school environment, the project design includes the following elements: development of materials appropriate to the setting; staff development and support; institutionalization and dissemination of materials throughout an established network and evaluation research to further knowledge about informal math and after-school programming. Project goals are to: provide free math materials to all participating after-school staff; produce a significant increase in informal math training for the after-school workforce; strengthen the role of informal math in after-school settings; and conduct and disseminate research on the project in terms of its impact on after-school programming, informal math education and the math "achievement gap." "Mixing in Math" national partners will facilitate further reach of the project. The National Institute of Out of School Time (NIOST) in addition to posting materials on their website, will incorporate project activities into their staff development programs. Ceridian, a work-life benefits provider, will distribute project materials to workplace school-ages childcare programs.
WGBH's Science Unit is requesting funds to produce for NOVA a two-hour television special based on David Bodanis' book "E=mc2: A Biography of the World's Most Famous Equation." Combining dramatic and documentary techniques, the program uses Einstein's iconic equation to explore the physics behind the equation and the nature of the scientific process. A media initiative, an interactive Web site, and an outreach campaign broaden the program's impact beyond the television broadcast. "E=mc2" is intended for prime-time broadcast on PBS in the fall of 2005, to coincide with the centennial of Einstein's "Miracle Year," and should reach an initial audience of seven million viewers. Outreach kits will be made available for free to 16,000 public libraries and 1,000 after-school programs. Notification of educational resources will be sent to all 14,000 high school physics teachers around the country. A formative evaluation of the program and a summative evaluation of the program and outreach materials will ensure that "E=mc2" achieves its ultimate purpose: to enhance public understanding of science and promote scientific careers. Key Project Personnel: Director of the WGBH Science Unit and Senior Executive Producer of NOVA: Paula S. Apsell Writer/Director: Kevin Macdonald Producer: John Smithson Formative Evaluation: Multimedia Research Summative Evaluation: Goodman Research Group
Understanding the Science Connected to Technology (USCT) targets information technology (IT) experiences in a comprehensive training program and professional support system for students and teachers in science, technology, engineering and mathematics (STEM). Participants have opportunities to assume leadership roles as citizen volunteers within the context of science and technology in an international watershed basin. Training includes collection, analysis, interpretation and dissemination of scientific data. BROADER IMPACTS: Building on a student volunteer monitoring program called River Watch, the USCT project enables student scientists to conduct surface water quality monitoring activities, analyze data and disseminate results to enhance local decision-making capacity. The project incorporates state and national education standards and has the potential to reach 173 school jurisdictions and 270,000 students. USCT will directly impact 81 teachers, 758 students and 18 citizen volunteers. The USCT project provides direct scientist mentor linkages for each participating school. This linkage provides a lasting process for life-long learning and an understanding of how IT and STEM subject matter is applied by resource professionals. Broader impacts include accredited coursework for teachers and students, specialized training congruent with the "No Child Left Behind Act of 2001," and building partnerships with Native American schools. INTELLECTUAL MERIT: The USCT project is designed to refocus thinking from static content inside a textbook to a process of learning that includes IT and STEM content. The USCT engages students (the next generation of decision makers) in discovery of science and technology and expands education beyond current paradigms and political jurisdictions.
This project develops an 8-week middle-school mathematics module that introduces cryptography, the science of sending secret messages, while teaching and reinforcing the learning of related mathematical concepts. The topics range from the classical encryption systems and the historic context in which they were used through powerful modern encryption systems that provide secrecy in electronic messages today. The module also covers passwords and codes that correct errors in the transmission of information. Public awareness of the importance of cryptography is growing, as is the need to understand the issues involved. The study of cryptography provides an interesting context for students to apply traditional mathematical skills and concepts. Mathematical topics covered include percents, probability, functions, prime numbers, decimals, inverses and modular arithmetic. The main product is a middle-school student book, with accompanying teacher materials. A web site is being developed that supports the activities in this book. Abbreviated modules for Grades 3, 4 and 5 are also being developed, as well as an instructor's guide for adapting the materials for use in informal educational settings such as museums and after-school programs. The development of the module involves piloting and field-testing by experienced classroom teachers from diverse school communities and instructors of informal educational programs. Evaluation includes review by mathematicians and educators, as well as an investigation into the level of students' understanding of the topics studied.
The Developmental Studies Center (DSC) will implement "Home, School and Community: AfterSchool Math for Grades 3-5," a program that targets at-risk and low income children in afterschool programs. AfterSchool Math trains youth workers to help students in grades 3-5 better understand measurement and geometry concepts, building on the success of the NSF-funded Home, School and Community mathematics program for grades K-2 (ESI #97-05421). The project develops, field-tests and evaluates thirty math games and ten story guides, which support the social and mathematical development of children, while emphasizing cooperative learning. The content for all materials will be aligned with national standards in mathematics. A 12-hour professional development workshop for youth workers and an 18-hour workshop for facilitators or youth worker leaders are also planned. Two training videos and a facilitator manual will be produced to support this aspect of the project. Field testing will occur in Kansas, Louisiana and Missouri. This proposal has been augmented to include a special emphasis on rural communities which doubles the number of field test sites from 50 to 100. A Rural Outreach Specialist will conduct focus group meetings to determine needs unique to rural programs and lead the field testing in these communities. It is anticipated that over 3,200 youth workers will be trained and a national cadre of more than 300 youth worker leaders will be created.