The Coalition for Science After School was launched January 28, 2004 at the Santa Fe Institute, home to the world’s leading researchers on the study of complexity. Against the dazzling backdrop of the New Mexican mesa, 40 educational leaders from diverse but overlapping domains—science, technology, engineering and mathematics education and after-school programs—met to grapple with three emerging, important trends in youth development and science learning in this country: 1. An explosion in the number of U.S. youth attending after-school programs, and increasing links between school and after
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TEAM MEMBERS:
The Coalition for Science After SchoolLeah Reisman
From March 26-28, 2014, the Coalition for Science After School (CSAS) hosted its final summit, Passing the Torch: Advancing Opportunity for Quality Science Learning. The Summit was intended to: (1) celebrate a decade of progress in strengthening and expanding STEM learning opportunities in out-of-school time; (2) call attention to critical issues in ensuring that all young people have opportunities for quality STEM experiences in their local communities; and (3) stimulate ideas, strategies, partnerships and commitments to continue to increase opportunities for quality STEM experiences across
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TEAM MEMBERS:
The Coalition for Science After SchoolLeah Reisman
The Decapoda - shrimp, lobsters, and crabs - are an economically important, diverse group of animals whose geologic history extends back 400 million years. Living representatives, numbering over 15,000 species, are global in distribution and nearly ubiquitous in oceanic and non-oceanic environments. They exert a major impact on ecosystems; understanding the dynamics of their fossil record will illuminate their historical impact on ecosystems. We will test the hypothesis that decapods are arrayed in a series of discrete evolutionary faunas; remarkably, the vast array of living and fossil decapods in diverse interrelated groups have exploited four basic body plans repeatedly. Other hypotheses to be tested are that the Decapoda have repeatedly adopted a limited number of baupläne, or generalized architectures, throughout their history; that they have experienced explosive evolutionary radiations followed by periods of no determinable change; and that they are generally resistant to mass extinction events. These hypotheses will be tested using a unique dataset compiled and assessed by the Principle Investigators: a compilation of all fossil decapod species, arrayed in a classification scheme including fossil and living taxa, with geologic and geographic ranges of all species, including a phylogeny (i.e. "family tree") for many sub-groups within the Decapoda. The dataset will be expanded to include ecological data for each taxon and will be entered into the Paleobiology Database, an NSF-supported vehicle for analyzing the fossil record. Employing its methodology, patterns of diversity and macroevolution of the decapods will be generated at levels ranging from the entire Order to species level. This will result in a comprehensive analysis of macroevolutionary patterns of this major group for the first time. Available paleoecological data derived from field studies and published records will be used to determine the effects of various environmental factors such as seafloor conditions, reef development, water depth, and temperature on morphology, extinction survivorship, and diversity. Because decapods have a remarkable range of morphological variation preservable in the fossil record, the diversity of the groups of decapods can be assessed in relation to their morphological characteristics. Defining the history of taxa with specialized morphology will permit recognition of body plans that have been exploited by different decapod groups throughout the history of the clade.
Intellectual merit. This study will provide the most comprehensive analysis of macroevolution of the Decapoda yet conducted, all based upon a unique dataset that is internally consistent by virtue of its having been developed entirely by the investigators. It will document the significance of employing a high resolution, species-level database for interpretation of diversity. The hypotheses and conclusions derived here will provide a model and the foundation for future work on Decapoda, Arthropoda, and macroevolution of well-constrained groups. It will provide a test for the efficacy of PBDB data versus a constrained dataset assessed by specialist systematists.
Broader impacts. The work will introduce undergraduate students at Kent State at Stark, an undergraduate campus, and Kent State at Kent, to research that involves paleoecological, paleogeographical, and functional morphological elements which, in turn, will be communicated to other students. Because decapods are known to virtually everyone, they form an excellent group to use to inform the public about ancient patterns of diversity and the relationship between the morphology of organisms, variations in their environmental requirements, and their adaptability to different physical conditions. This will be conveyed in a professionally constructed display which has the potential to be exhibited in museums and universities around the country. Small kits designed for use in elementary and middle schools will be available to allow students to make their own observations about the adaptations of decapods to their environment and its effect on diversity. Published papers and presentations on results of research at meetings will be prepared throughout the course of the research. Because the study of modern biodiversity is a concern of the general public, presentations to broader audiences as well as geology classes will provide a broad historical context for understanding modern patterns of diversity. Data entered into Paleobiology Database and Ohio Data Resource Commons will be openly available to other researchers and the general public. Combined, the databases will assure archival storage and public access, following a proprietary period.
What makes “making”—the next generation of inventing and do-it-yourself—worth paying attention to? In this report, we explore the three categories of makers, the ecosystem growing around those categories, the role technology plays in this ecosystem, and, finally, how business can take advantage of the opportunities this movement represents.
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TEAM MEMBERS:
John HagelJohn Seely BrownDleesha Kulasooriya
Virtual Missions and Exoplanets (vMAX) will develop and test a three-dimensional, virtual world environment that will engage middle school students and educators from high-poverty schools in NASA-related exoplanet mission simulations. The Patricia and Phillip Frost Museum of Science will serve as the lead institution, in partnership with the following institutions: U.S. Space and Rocket Center, New York Hall of Science, Chabot Space & Science Center, and Sci-Port: Louisiana¹s Science Center; Aimee Weber Studios will be responsible for virtual exhibit fabrication, and WestEd will serve as the project¹s formative and summative evaluator. The overall goal of the project is to create a NASA resource on exoplanet astronomy that will engage students, educators, and the general public in NASA¹s search for worlds beyond our own. The project aims to increase underserved students¹ engagement in STEM, knowledge of exoplanet missions, and awareness of NASA-related careers; and advance the growing body of knowledge on the use of virtual world technologies to provide opportunities for students to participate in NASA Mission-related science teaching and learning. The project will result in the development of vMAX world, a virtual world with simulations related to exoplanet astronomy designed for use as the core content of a 30-hour out-of-school learning experience for middle school students. An Educator Implementation Guide will be developed and made available online for download by secondary school teachers and science museum educators. In addition, an interactive, multiuser exhibit kiosk, utilizing the simulations created for vMAX world, will be developed and made available to interested Visitor Centers, museums and planetariums.
The Virginia Air & Space Center (VASC): Creating an Exciting NASA Inspired Education Program was a two-year project to develop and deliver teacher workshops, classroom outreach visits to students of those teachers, and on-site educational experiences for those students, which introduce and reinforce NASA STEM resources. These are followed up by surveys from the teachers and students for evaluation purposes. The VASC partnered with the National Institute of Aerospace (NIA) and NASA Langley Research Center to develop and deliver 15 professional development workshops to a total of 185 formal and informal educators. NASA materials were aligned to the Virginia Standards of Learning guidelines (SOLs) for ease of integration into the teachers’ curricula. The goal was to provide six professional development workshops, but we delivered 15 workshops, 250% of our goal. Of the 185 educators who attended the workshops, 155 were formal classroom teachers, and 30 were informal educators. NASA STEM outreach programs were delivered to 8,437 students ranging from grades K-12. On-site NASA STEM programs were presented to 2,507 students at VASC. Pre-and post-program surveys were collected and evaluated from both outreaches and on-site programming. This informal education program helped to increase awareness of NASA's contributions to scientific knowledge and fulfill NASA's three major Education goals, namely: (1) strengthen NASA and the nation's workforce; (2) attract and retain students in STEM disciplines, and (3) engage Americans in NASA's mission, and VASC staff was able to build exciting new partnerships and programs with the different school systems in the Hampton Roads area.
The Nature Research Center is a project through which the North Carolina Museum of Natural Sciences provides NASA with a permanent presence through the creation of NASA-themed exhibits in its new wing (the Nature Research Center), hosting special events, educator workshops and special programming, all of which serve the general population and seek to improve understanding of and engagement with science. The lead institution is the North Carolina Museum of Natural Sciences. Goals, expected and actual outcomes are as follows: Exhibits in the new wing were expected to reach 200,000 individuals in its inaugural year; in only 8 months, the Museum has welcomed over 1 million visitors. Astronomy Days’ goal was to reach 20,000 people per year and is on target for meeting this goal. Educator Workshops’ goal was to reach 32 educators per workshop and is on target for meeting this goal. The Museum’s visitor base has demonstrated an insatiable desire for NASA-themed programs. Attendance at Astronomy Days remains impressive and special space events (such as the transit of Venus, or live downlinks with the International Space Station) attract larger-than-expected audiences. The Museum appreciates NASA’s support and is eager to continue providing NASA with an ongoing presence in Raleigh, NC.
The Dynamic Earth: You Have To See it To Believe It is a public exhibition and suite of programming designed to educate and excite K-8 students, teachers, and families about weather and climate science, plate tectonics, erosion, and stream formation. The Dynamic Earth program draws attention to the importance of large-scale earth processes and the human impacts on these processes, utilizing real artifacts, hands-on models, and NASA earth imagery and data. The program includes the exhibition, student workshops, family workshops, annual professional development opportunities for classroom teachers, innovative theater shows, lectures for adults by visiting scientists, and interpretive activities. The Montshire Museum of Science has partnered with Chabot Space and Science Center (CA) and the US Army Corps of Engineers Cold Regions Research and Engineering Laboratory (NH) on various components. The project has broadened our internal capacity for providing quality earth science programming by greatly expanding our program titles and allowing us to create hands-on materials for use by our educators and to loan to schools in our Partnership Initiative. Programming developed during the grant period continues to reach thousands of students and teachers each year, both on-site and as part of our rural outreach efforts.
The Iowa Children’s Museum designed and built a new aviation exhibit, Take Flight: The Science of Aviation, that delivers NASA’s Informal Education Program to the public by providing high-quality active learning experiences for children and their families outside the formal school classroom setting. This exhibit is a vehicle through which NASA and the Museum build public understanding of the key science, technology, engineering, and math disciplines that make it possible for humans to safely fly through the atmosphere.
The Museum has developed the following products/deliverables to support our project goals.
1. Created a comprehensive Take Flight! Exhibit Guide will be developed for three different types of users: Adult and Child Museum Visitors, Educators, and Museum Staff
2. Created revised curriculum for a week-long Summer Day Camp Aeronautics program and girl and boy scout programs
3. Created additional “Fun-tivities” themed around aviation for general public
Partners include University of Iowa Science Education Center, University of Iowa Delta Center for Brain Development , University of Iowa Women in Engineering, University of Iowa Engineering School, Iowa State University Extension, Grantwood Area Education Agency, 21st Century After School Program, Iowa After School Alliance, Mississippi Valley Girl Scouts, Boy Scouts of America, Iowa City and Cedar Rapids Community School Districts, and STEM Regional Networks of Iowa.
STEMtastic: NASA in Our Community is a two-year project designed to educate and inspire teachers, students and life-long learners to embrace NASA STEM content. The project will increase awareness of NASA activities, while educating and inspiring students to train for careers that are critical to future economic growth of the country in general, and NASA’s future missions in particular. The Virginia Air & Space Center (VASC) will partner with the Virginia Space Grant Consortium and Analytical Mechanics Associates, Inc. to accomplish this project. VASC will deliver NASA STEM content through (1) STEMtastic Teacher Institutes and Education Modules: (a) a series of two five-day professional development institutes for educators which will result in the (b) development and dissemination of new education modules for grades 4-9; and (2) STEMtastic Exhibits and Demonstrations: new interactive exhibits to used for live demonstrations at VASC; those demonstrations will also be delivered to traditionally underserved schools in the region. All classroom and teaching materials—educator institutes, education modules, exhibit software and demonstration modules—will be developed using NASA content and shared with other institutions to promote the expansion of knowledge about best practices in providing STEM education in both formal and informal education settings. STEMevals, a robust evaluation plan, will be implemented to assess success in each project area. Adjustments will be made along the pipeline to increase effectiveness in reaching the target audience. The project has the potential to reach countless educators, students and museum visitors throughout the U.S."
The primary purpose of the STARS: Strengthening Teaching, Awareness and Resources in Science project from the Challenger Learning Center of the San Joaquin Valley is to build upon the CLC's resources and partnership in order to maximize the impact of informal science education in creating a STEM pipeline for the San Joaquin Valley region. The goals are to promote lifelong learning among the general public regarding STEM fields and NASA's contribution to American society through a series of high-profile community events, strengthen K-12 partnerships to ensure the long-term utilization of the CLC as a STEM education resource, and further develop the CLC's partnership with the University of California Merced to ensure continuity of the STEM pipeline from K-12 to higher education, integrating informal science education to inspire students to pursue STEM learning throughout this progression.
Pipeline for Remote Sensing Education and Application (PRSEA), will increase awareness, knowledge and understanding of remote sensing technologies and associated disciplines, and their relevance to NASA, through a combination of activities that build a “pipeline” to STEM and remote sensing careers, for a continuum of audiences from third grade through adulthood. This program will be led by Pacific Science Center. The first objective is to engage 50 teens from groups underrepresented in STEM fields in a four-year career ladder program; participants will increase knowledge and understanding of remote sensing as well as educational pathways that lead to careers in remote sensing fields at NASA and other relevant organizations. The second objective is to serve 2,000 children in grades 3-5, in a remote sensing-based out-of school time outreach program that will increase the participant’s content knowledge of remote sensing concepts and applications and awareness and interest in remote sensing disciplines. PRSEA’s third objective is to engage 180 youth, grades 6-8, in remote sensing-themed summer intensive programs through which youth will increase knowledge of remote sensing concepts and applications and increase awareness and interest in educational and career pathways associated with remote sensing and NASA’s role in this field. The final objective is to engage 10,000 visitors of all ages with a remote sensing-themed Discovery Cart on Pacific Science Center’s exhibit floor. By engaging in cart activities, we anticipate visitors will increase their level of awareness and interest in the topic of remote sensing and NASA’s role in contributing to this field.