The Thames Science Center collaborative with the resources of the Smithsonian Astrophysical Observatory, Wesleyan University and the National Air and Space Museum will design and develop the project, "Shoot For the Moon." This science education project will capitalize on the attraction, familiarity and proximity of the moon using it as a basis to enrich and supplement the eight and ninth grade physical science curriculum. Ten classroom units, complimentary experiments and demonstrations will be developed. "Moonwatch" software and audio visual materials, including an instructional videotape and a multi.image presentation will accompany the units. Sixteen teachers and museum educators will participate in the training, evaluation and testing as the project is integratedinto the curriculum of twelve schools and four museums. The project is designed to be replicated in schools and science centers in different geographical locations nationally. The site for development and testing will be the Thames Science Center, a regional science museum in eastern Connecticut. The science center offers formal science enrichment programs and tours for students and teacher professional development programs throughout the region.
The Pacific Science Center, in collaboration and with support from the Washington NASA Space Grant Consortium, proposes a three-year program to develop and test a model for delivering mid-scale, astronomy and space-themed exhibits and programming in a shopping center environment, especially in rural locations. The program targets an audience that does not have easy access to a science center or that may not be inclined to take advantage of such a facility. The exhibits and curriculum for this project will be based on Pacific Science Center's well-tested Space Odyssey Van Program, which presently tours elementary schools in Washington State. Phase One of the project will be a test delivery of the existing exhibits and programming to two malls. Phase Two involves construction and testing of the final, larger exhibits and reworking existing programming to better fit a mall delivery environment. Phase Three takes the newly tested devices to ten malls in suburban and rural Washington.
Communicating Ocean Sciences to Informal Audiences (COSIA) is an innovative project that creates unique partnerships between informal science education institutions and local colleges conducting research in ocean sciences, with an emphasis on earth, biological and geochemical sciences. The project enables over 100 undergraduate and graduate students that are enrolled in the Communicating Ocean Sciences college course to create engaging learning activities and teaching kits in conjunction with their informal education partners. Institutional teams include: Long Beach Aquarium and California State University-Long Beach; Hatfield Marine Science Center and Oregon Sea Grant at Oregon State University; Virginia Aquarium and Science Center and Hampton University; Liberty Science Center and Rutgers University; and Lawrence Hall of Science and University of California-Berkeley. Students learn valuable outreach skills by providing visiting families and children with classes, guided tours and interactive learning experiences. Deliverables include a three-day partner workshop, a series of COSIA Handbooks (Collaboration Guide, Informal Education Guide and Outreach Guide), an Informal Science Education Activities Manual and Web Bank of hands-on activities. Strategic impact will be realized through the creation of partnerships between universities and informal science education institutions and capacity building that will occur as informal science institutions create networks to support the project. It is also anticipated the evaluation outcomes will inform the field abut the benefits of museum and university partnerships. The project will impact more than 30,000 elementary and middle school children and their families, as well as faculty, staff and students at the partnering institutions.
The Space Science Institute is establishing a museum educator/theater network of eight museums around the country, pairing larger with smaller institutions. The Association of Science-Technology Centers and the Astronomical Society of the Pacific also are collaborators. The primary audience is informal science education museum educators; secondary audiences are museum visitors experiencing the to-be-developed programs. The Science Theater Education Programming System (STEPS) is a technology that has been developed by the PI and others. The team will be continuing to expand the capability of the system for this project, and the partnering museums are collaboratively creating an initial set of theater programs on astrobiology, along with a suite of training programs and communication formats for educators. The STEPS technology allows these programs to be delivered both on site and via outreach, depending on the goals of each organization. The intent is to form the core of a community of practice that would enhance the professional capacity and identities of informal educators. The theater program format is positioned as a flexible, low-cost alternative to traveling exhibits, particularly for the smaller institutions. Deliverables include: the establishment of the network, the STEPS system and programs, professional development tutorials and workshops, evaluation of the programs, and a research project and report examining the network as a community of practice and vehicle for strengthening the professional identities of museum educators.
These 16 articles offer a gentle introduction to nano science and technology, and can be used as marketing pieces for discussing nano with the press during NanoDays or other nano event promotion.
This guide to partnering with researchers and scientists is designed for the U.S. science museum community, and was produced by the Strategic Projects Group at the Museum of Science, Boston, for the NISE Network. Note: Beta Site, under development
The Lunar and Planetary Institute (LPI) will use $286,915, or 67% of a $430,373 total project budget, over three years to develop "SkyTellers," a space science and astronomy resource for small informal (and formal) learning settings such as planetariums, museum classes, school and community libraries, youth groups and home school settings. LPI educators and science staff, in consultation with a Native American master story teller, evaluation consultants, and an advisory board, will develop 12 SkyTeller topics. Each SkyTeller topic pairs a myth or legend (primarily but not exclusively Native American) with a relevant science story (Sky Story/Science Story) that explains our current understanding of the phenomenon that the ancient tale sought to explain. Ancillary materials (illustrations produced by LPI graphics staff, images from the latest in space science missions and research) will complete the 12 story sets to be used by informal and formal science educators at a variety of venues. Extensive formative and summative evaluation (alpha and beta testing) at multiple test venues is designed to insure high quality informal science education products.
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Stephen MackwellStephanie ShippJoseph Hahn
resourceresearchProfessional Development, Conferences, and Networks
This research agenda is a living document, constructed in response to on-going field-wide conversations following the 21st Century Natural History Settings Conference at the Smithsonian Museum of Natural History. At the conference, natural history professionals explored new directions for museums and other natural history institutions, including zoos, aquaria, botanical gardens, and nature centers. The research agenda is intended to be edited, discussed, and fleshed out by the field as we work together and make progress. New research questions will emerge spurred by surprising findings
Making Connections, a three-year design-based research study conducted by the Science Museum of Minnesota in partnership with Twin Cities' communities, is developing and studying new ways to engage a broader audience in meaningful Maker experiences. This study draws and builds on existing theoretical frameworks to examine how community engagement techniques can be used to co-design and implement culturally-relevant marketing, activities, and events focused on Making that attract families from underrepresented audiences and ultimately engage them in meaningful informal STEM learning. The research is being done in three phases: Sharing and Listening - co-design with targeted communities; Making Activities Design and Implementation; Final Analysis, Synthesis and Dissemination. The project is also exploring new approaches in museums' cross-institutional practices that can strengthen the quality of their community-engagement. In recent years, Making - a do-it-yourself, grassroots approach to designing and constructing real things through creativity, problem-solving, and tool use - has received increasing attention as a fruitful vehicle for introducing young people to the excitement of science and engineering and to career skills in these fields. Maker Faires attract hundreds and thousands of people to engage in Making activities every year, and the popularity of these events, as well as the number of museums and libraries that are beginning to provide opportunities for the public to regularly engage in these types of activities, are skyrocketing. However, Maker programs tend to draw audiences that are predominantly white, middle class, male, well educated, and strongly interested in science, despite the fact that the practices of Making are as common in more diverse communities. Making Connections has the potential to transform how children begin to cultivate a lifelong interest in engineering at a young age, which may ultimately encourage more young people of color to pursue engineering careers in the future.
This project's interdisciplinary team will carry out research and training that will identify ways for professionals in science, technology, engineering, and mathematics (STEM) to engage with public audiences that currently lack the community connections, resources, time, or know-how to gain access to science education and to scientists. The project will create real and on-line materials for scientists to convey the excitement, content, and relevance of their own research to public groups whose values, professions, or aesthetic and cultural backgrounds are connected to that research topic. The project will also foster ways for scientists to understand that members of the public can provide valuable input to science. Research and evaluation on the development of this innovative public engagement model "the STEM Ambassador Program (STEMAP)" will be conducted to provide insights into the effectiveness and extensibility of the STEMAP model. This approach integrates three existing elements of science engagement that have previously not been linked: design thinking, informal science education communication skills from museum work, and connecting scientists' research with the existing values of particular community groups. Robust evaluation will enhance effectiveness of in-person and online trainings; research will provide understanding of how different science learning models can be integrated and enhanced for public audiences and for scientists. This project is funded by the Advancing Informal STEM Learning (AISL) program, which seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. This includes providing multiple pathways for broadening access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants. Science and society need innovative and transformative ways to interact synergistically. Given the deep knowledge and contagious passion for their research, STEM professionals can bring unique assets to directly engage public audiences, especially important the traditionally underserved public groups. Members of the public in turn have the potential to provide novel ideas, data, and insights to support researchers. The project's exploratory research will help understand how STEM professionals can broaden participation by themselves engaging unengaged publics with the excitement of science and science knowledge in ways that are congruent with academic rewards. The project team will integrate three existing NSF-funded models: a) Research Ambassador Program, b) Portal to the Public, and c) Design Thinking. A cadre of faculty and graduate students will be trained in "STEM Ambassadors" workshops, in which social scientists and community group representatives will help STEM Ambassadors identify public groups with interests that connect to the scientist's research. Engagement events will occur in community venues, e.g., churches, factories, and day care centers, etc. Case studies and evaluation instruments answer research questions about: the role of empathy in the formation and change of identity; relationships between public audiences, mode of engagement, and identity shifts; and motivational drivers for STEM Ambassadors and public audiences. The intellectual merit is the training and evaluating of 50 STEM Ambassadors (via 100 outreach events involving approximately 5000 individuals from community groups); strategies that encourage STEM professionals to engage with underrepresented publics; and insights on how to integrate multiple education models. STEMAP will disseminate its findings and new resources through the STEMAP website. In addition, the dissemination efforts will be extended through: collaboration with the NSF-funded PoPNet Expansion Project and the Centers for Science and Mathematics Education (CSMEs); presentations at national science professional organizations, such as the AAAS, as well as through the CAISE Wiki and the National Alliance for Broader Impacts (NABI). STEMAP will create a process for other NSF PIs to generate, evaluate, and articulate their research and its applications to public groups that lie far outside academia.
The Seeing Scientifically project will research a new way of supporting museum visitor experiences so they can have authentic scientific observation of live microscopic specimens. By adapting existing computational imaging techniques from current biological research, the project aims to encourage and support visitors in observing scientifically, that is, in asking productive questions, interpreting image-rich information, and making inferences from visual evidence that increasingly characterizes current biological research. The scaffolding (e.g., visual cues or information supporting learning) will consist of a system of virtual guides and prompts that are responsive to what visitors see. The scaffolding prompts will be overlaid on a real time, high-density image of a live sample that the visitor is investigating with a research grade microscope. Project research will contribute early knowledge on ways to scaffold informal learners in the practice of authentic scientific observation with the complex, dynamic visual evidence that scientists themselves see using the equipment and techniques they use. Project research and resources will be widely disseminated to learning science researchers, informal science practitioners, and other interested audiences through publications, conference presentations and sharing of resources via the NSF-supported informalscience.org website and other relevant websites. 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 includes providing multiple pathways for broadening access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants. The project will prototype an innovative microscope exhibit that scaffolds visitors in scientific observation of live specimens and their biological processes. The overarching hypothesis is that scientific observation of real-time visual phenomena can deeply engage learners with the content, tools and practices of modern science, which increasingly rely on image-based data. Through three rounds of iterative prototype development and evaluation, the project will generate early findings for the following related questions: (1) what are promising ways of scaffolding observation of live specimens at an unmediated exhibit; (2) How can computational imaging techniques be integrated into a microscope exhibit to engage and scaffold learners to ask productive questions, interpret what they see, and make evidence-based inferences from complex, dynamic images. Data will be collected and analyzed by coding think-aloud interviews with visitors concerning their interest in and description of the biological phenomenon observed; coding of think aloud transcripts of visitor questions types and answers, relevant features noted, inferences and scaffold use; and statistical comparison of holding time, questions asked, answers, inferences, and scaffold use. Project findings will seed more rigorous research on the combination of scaffolding and computational imaging techniques effective for supporting scientific observation in image-rich areas of science.