Most communities have afterschool programs that give school-aged students a safe place to go after the dismissal bell rings. The next step after simply providing a safe haven is to create a nurturing environment that develops young people’s talents and supports their needs. A formal mentoring program can help to achieve this goal.
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TEAM MEMBERS:
Sara McDanielAnna-Margaret YarbroughKevin Besnoy
What is “the truth” about out-of-school time (OST) work with boys and young men of color (BYMOC)? How has the literature that documents the increasing public consciousness of this work influenced program centers and policy debates? Recent local and national attention on the crisis facing BYMOC has contributed many insights to this discussion. Although My Brother’s Keeper was not the first call to action on this issue, this White House initiative has raised awareness and resources, some of which have been directed toward developing and documenting efforts undertaken outside the academic day.
Positive youth development and youth organizing are strengths-based approaches to the lives, needs, and contributions of young people (Damon & Gregory, 2003). These approaches privilege the voices of youth as they engage with issues in their communities and challenge institutions to respond. Few studies, however, have explored the role of positive youth development and youth organizing initiatives among immigrant youth of color. The challenging terrain of modern urban life requires these youth to navigate the political, economic, and legal demands confronted by their families; to understand
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TEAM MEMBERS:
Anthony de JesusSofia OviedoScarlett Feliz
The Wild Center will develop, implement, and disseminate a model program, VTS in Science, for the science museum field adapted from the Visual Thinking Strategies (VTS) teaching method. In partnership with several museums, educators, and a consulting firm, the Wild Center will use current research to develop informal and formal learning programming; implement a model professional development program for science museum professionals and elementary teachers; provide educators resources and knowledge to develop VTS in Science programming relevant to daily teaching—including a VTS in science toolkit; facilitate a long-term collaborative process and model school-museum partnership among a diverse group of education providers; and evaluate the effectiveness of the VTS in Science program in order to promote replication by science museums nationally.
The Cyberlearning and Future Learning Technologies Program funds efforts that support envisioning the future of learning technologies and advance what we know about how people learn in technology-rich environments. In this Cyberlearning EAGER project, the project team is developing foundations for using "paper mechatronics" as a learning technology. Paper mechatronics makes possible a craft-oriented approach to engineering and computing education that integrates key concepts from mechanical engineering, electrical engineering, control systems, and computer programming, while using paper as the primary material for learner design, exploration, and inquiry. In this approach, learners will design foldable paper components and assemblies; program motors, sensors and controls; test their ideas iteratively; and share their designs on a website. This paper-based modeling approach to learning concepts in and practices of mechanical engineering, electrical engineering, control systems, and computer programming ultimately aims to make it possible for all learners to have exposure to and the opportunity to participate in creative engineering, design, and computer programming.
The approach to learning through designing and making through paper mechatronics is made possible by a convergence of many different technological factors -- the array of small computers, sensors, and actuators that are becoming available at low cost and a size that children can use; availability of a wide variety of manipulable conductive materials (threads, paints, fabrics); low-cost and precise desktop and laser cutters for paper and similar materials; a wide variety of novel paper-like materials; and new ways of interacting with the computer. The approach has its foundations in Papert's constructionism and in the current maker movement, but it has potential beyond constructionism itself, both in practice and with respect to what can potentially be learned about learning and development in in context of its use.
Hidden Universe is a multi-faceted project built around production of a 2D/3D giant screen film. The goal is to inspire, engage, and excite viewers about the mysterious worlds hidden around us and the science and technology that reveal them. The film will illuminate natural wonders that are invisible to the naked eye, such as objects and processes that are too slow, too fast, and too small to be seen without advanced technologies. It will include nanoscience and microbiology research and developing wavelength technologies such as ultrafast lasers. The project will employ cutting-edge
The Space Science Institute is developing an astronomy educational social game for the Facebook platform. The game uses the "sporadic play" model popular with many Facebook games, in which players take only a few actions at a time, then return to explore the results. Here players will create their own stars and planetary systems that evolve over time at a rate of a million years a minute. Players set systems in motion, revisiting the game over days or weeks to make new choices and alter strategies. The game is in effect an end-to-end solar system simulation, following a star from birth to death. As a result it encompasses a wide variety of core concepts in astronomy, including galactic structure, stellar evolution and lifecycles, planetary formation and evolution, and habitability and "habitable zones." The accompanying research program will examine the effectiveness of this type of game in informal education, and the effects of the social network on meeting the education goals, including viral spread, cooperative play, and discussions about the game and its underlying content in associated online forums.
The National Writing Project (NWP) is collaborating with the Association of Science-Technology Centers (ASTC) on a four-year, full-scale development project that is designed to integrate science and literacy. Partnerships will be formed between NWP sites and ASTC member science centers and museums to develop, test, and refine innovative programs for educators and youth, resulting in the creation of a unique learning network. The project highlights the critical need for the integration of science and literacy and builds on recommendations in the Common Core State Standards and the National Research Council's publication, "A Framework for K-12 Science Education: Practices, Crosscutting Concepts, and Core Ideas." The content focus includes current topics in science and technology such as environmental science, sustainability, synthetic biology, geoengineering, and other subjects which align with science center research and exhibits. The project design is supported by a framework that incorporates a constructivist/inquiry-based approach that capitalizes on the synergy between rigorous science learning and robust literacy practices. Project deliverables include a set of 10 local partnership sites, professional development for network members, a project website, and an evaluation report highlighting lessons learned. Partnership sites will be selected based on interest, proximity, history, and expertise. Two geographically and demographically diverse cohorts, consisting of five partnerships each will be identified in Years 2 and 3. Each set of partners will be charged with creating a comprehensive two-year plan for science literacy activities and products to be implemented at local sites. It is anticipated that the pilot programs may result in the creation of new programs that merge science and writing, integrate writing into existing museum science programs, or integrate science activities into existing NWP programs. Interest-driven youth projects such as citizen science and science journalism activities are examples of programmatic approaches that may be adopted. The partners will convene periodically for planning and professional development focused on the integration of science and literacy for public and professional audiences, provided in part by national practitioners and research experts. A network Design Team that includes leadership representatives from NWP, ASTC, and the project evaluator, Inverness Research, Inc., will oversee project efforts in conjunction with a national advisory board, while a Partnership Coordinator will provide support for the local sites. Inverness Research will conduct a multi-level evaluation to address the following questions: -What is the nature and quality of the local partner arrangements, and the larger network as a whole? -What is the nature and quality of the local science literacy programs that local partners initiate, and how do they engage local participants, and develop their sense of inquiry and communication skills? First, a Designed-Based Implementation Research approach will be used for the developmental evaluation to assess the implementation process. Next, the documentation and portrayal phase will assess the benefits to youth, educators, institutions, and the field using surveys, interviews, observations of educators, and reviews of science communication efforts created by youth. Finally, the summative evaluation includes a comprehensive portfolio of evidence to document the audience impacts and an independent assessment of the project model by an Evaluation Review Board. This project will result in the creation of a robust learning community while contributing knowledge and lessons learned to the field about networks and innovative partnerships. It is anticipated that formal and informal educators will gain increased knowledge about science and literacy programs and develop skills to provide effective programs, while youth will demonstrate increased understanding of key science concepts and the ability to communicate science. Programs created by the local partnerships will serve approximately 650 educators (450 informal educators and 200 K-12 teachers) and 500 youth ages 9-18. Plans for dissemination, expansion, and sustainability will be undertaken by the sub-networks of the collaborating national organizations drawing on the 350 ASTC member institutions and nearly 200 NWP sites at colleges and universities.
This full scale research and development collaborative project between Smith College and Springfield Technical Community College improves technical literacy for children in the area of engineering education through the Through My Window learning environment. The instructional design of the learning environment results from the application of innovative educational approaches based on research in the learning sciences—Egan's Imaginative Education (IE) and Knowledge Building (KB). The project provides idea-centered engineering curriculum that facilitates deep learning of engineering concepts through the use of developmentally appropriate narrative and interactive multimedia via interactive forums and blogs, young adult novels (audio and text with English and Spanish versions), eight extensive tie-in activities, an offline teachers’ curriculum guide, and social network connections and electronic portfolios. Targeting traditionally underrepresented groups in engineering—especially girls—the overarching goals of the project are improving attitudes toward engineering; providing a deeper understanding of what engineering is about; supporting the development of specific engineering skills; and increasing interest in engineering careers. The project will address the following research questions: What is the quality of the knowledge building discourse? Does it get better over time? Will students, given the opportunity, extend the discourse to new areas? What scaffolding does the learning environment need to support novice participants in this discourse? Does the use of narrative influence participation in knowledge building? Are certain types of narratives more effective in influencing participation in knowledge building? Evaluative feedback for usability, value effectiveness, and ease of implementation from informal educators and leaders from the Connecticut After School Network CTASN) will be included. The evaluation will include documentation on the impact of narrative and multimedia tools in the area of engineering education. Currently, there is very little research regarding children and young teen engagement in engineering education activities using narrative as a structure to facilitate learning engineering concepts and principles. The research and activities developed from this proposed project contributes to the field of Informal Science and Engineering Education. The results from this project could impact upper elementary and middle-school aged children and members from underrepresented communities and girls in a positive way.
The University of Southern California (USC) will build on prior work to test a robust model for assessing player content engagement and social interactions within an augmented reality game (ARG). In partnership with No Mimes Media, USC will use machine learning algorithms to make automated player inferences to customize game play. The content focus of the game will span a range of STEM disciplines, with a special emphasis on earth science content and scientific investigation & experimentation reasoning. High school youth from underserved communities in Los Angeles will be recruited to participate in the endeavor. This pathways project will use various "rabbit hole" techniques to attract freshmen and sophomore students from partner charter schools to the online game. The rabbit hole strategies may include cryptic posters, inquisitive signs, & SQR codes strategically placed in plain and open view of the target group. The game will be fully accessible to the target group online. During the ARG experience, youth players will encounter STEM concepts and scientific problems. Antagonistic characters will promulgate scientific misconceptions and nonscientific reasoning and challenge players to employ their scientific knowledge and skills to level-up, gain badges, and move through the game. As game play persists, machine learning algorithms will gather data on the players learning competencies and social interactions within the game. These data will be aggregated and analyzed to assess learning and interactions within the ARG environment. Additional analyses will be conducted by the mixed methods approach the external evaluation group, CRESST, will employ for the project formative and summative evaluations. Approximately 300 youth, within the target grade levels, are expected to participate in the gaming experience. However, given that access to the game and assessment tools will expand beyond the target group, the potential reach of the project could be much greater. Further, the stated aim of the project is not only to produce a scalable model for broad implementation but it also endeavors to provide puppetmasters with research and assessment tools to create more individualized experiences and improved learning outcomes for players within ARG environments.
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TEAM MEMBERS:
Yu-Han ChangJihie KimRajiv Maheswaran
The University of California, Davis Tahoe Environmental Research Center (TERC), UC Davis W.M. Keck Center for Active Visualization in the Earth Sciences (KeckCAVES), ECHO Lake Aquarium and Science Center (ECHO), UC Berkeley Lawrence Hall of Science (LHS), and the Institute for Learning Innovation (ILI) will study how 3-D visualizations can most effectively be used to improve general public understanding of freshwater lake ecosystems and Earth science processes through the use of immersive three-dimensional (3-D) visualizations of lake and watershed processes, supplemented by tabletop science activity stations. Two iconic lakes will be the focus of this study: Lake Tahoe in California and Nevada, and Lake Champlain in Vermont and New York, with products readily transferable to other freshwater systems and education venues. The PI will aggregate and share knowledge about how to effectively utilize 3-D technologies and scientific data to support learning from immersive 3-D visualizations, and how other hands-on materials can be combined to most effectively support visitor learning about physical, biological and geochemical processes and systems. The project will be structured to iteratively test, design, and implement 3-D visualizations in both concurrent and staggered development. The public will be engaged in the science behind water quality and ecosystem health; lake formation; lake foodwebs; weather and climate; and the role and impact of people on the ecosystem. A suite of publicly available learning resources will be designed and developed on freshwater ecosystems, including immersive 3-D visualizations; portable science stations with multimedia; a facilitator's guide for docent training; and a Developer's Manual to allow future informal science education venues. Project partners are organized into five teams: 1) Content Preparation and Review: prepare and author content including writing of storyboards, narratives, and activities; 2) 3-D Scientific Visualizations: create visualization products using spatial data; 3) Science Station: plan, design, and produce hands-on materials; 4) Website and Multimedia: produce a dissemination strategy for professional and public audiences; 4) Evaluation: conduct front-end, formative, and summative evaluation of both the 3-D visualizations and science activity stations. The summative evaluation will utilize a mixed methods approach, using both qualitative and quantitative methods, and will include focus groups, semi-structured interviews, web surveys, and in-depth interviews. Leveraging 3-D tools, high-quality visual displays, hands-on activities, and multimedia resources, university-based scientists will work collaboratively with informal science education professionals to extend the project's reach and impact to an audience of 400,000 visitors, including families, youth, school field trip groups, and tourists. The project will implement, evaluate, and disseminate knowledge of how 3-D visualizations and technologies can be designed and configured to effectively support visitor engagement and learning about physical, biological and geochemical processes and systems, and will evaluate how these technologies can be transferred more broadly to other informal science venues and schools for future career and workforce development in these critical STEM areas.
Taking NPASS (National Partnerships for Afterschool Science) to Scale builds on a previously funded effort (DRL 0515549) designed to provide professional development for out-of-school time (OST) science trainers, administrators, and frontline staff in collaboration with the California School-Age Consortium, the Georgia Afterschool Investment Council, The After-School Institute, Minnesota School Age Child Care Alliance, University of Missouri-Columbia, University of New Hampshire, and the Ohio Child Care Resource and Referral Association. Rutgers University-New Brunswick. The primary target audiences for this project are OST science trainers, administrators of statewide OST networks and frontline staff as well as youth participating in afterschool programs, most of whom are from traditionally underserved and economically challenged groups. Deliverables include three-day, semi-annual train-the-trainer institutes; annual seminars for NPASS leaders; professional development tools; science kits; and the NPASS website. The project design consists of four levels of management and delivery. At Level 1, the NPASS2 primary partners, EDC and the Boston Children's Museum, provide three-day state-based OST Science Trainer Institutes on a semi-annual basis. The Science Trainer Institutes combine hands-on experience with pedagogical training in informal science learning, youth development, and the logistics of working with OST sites. During Level 2, the eight State Leadership Teams recruit two cohorts of OST practitioners to attend Science Trainer Institutes. The new Science Trainers then identify OST sites to attend a series of half-day science trainings in Level 3. Each session introduces and models new science projects for use in afterschool settings, including the NSF-funded Design It! or Explore It! materials. Finally, at Level 4, OST sites serving children from predominantly underserved and underrepresented populations are invited to join the NPASS2 initiative. OST sites receive a materials kit and guide for the activities at each training session. It is estimated that as many as 10 OST state leaders and 100 science trainers will be reached at 750 community sites serving 22,000 youth. The combined intervention has the potential to change the OST landscape. The project evaluation to be conducted by the Goodman Research Group (GRG) employs a longitudinal design to determine participants' growth over time and the magnitude of change among the variables. The formative evaluation is designed to assess the development of the project's deliverables while the summative evaluation focuses on professional audience impacts. The NPASS2 summative evaluation examines the OST science trainers, OST state network administrators, youth workers, and site administrators through a baseline survey, in addition to annual questionnaires and interviews of network administrators and OST site administrators. The pre-post design measures changes in trainers' understanding, attitudes, behavior, and skills related to informal STEM education research or practice. To maximize the efficiency and authenticity of the evaluation, GRG will use the SET/STEM Leader Competencies Rubric currently being developed jointly by EDC in collaboration with the National 4-H Council\'s SET PD Committee.