ASTRONOMY - HOW DO WE KNOW? is a 4100 sq. ft. exhibit and program package for Discovery Place that will: 1) interpret the physical and chemical nature of astronomical bodies in the Universe, highlighting the scientific processes used in their discovery, 2) interpret, through interactive exhibits and programs, the basic technologies of the scientific study of astronomy, and 3) function as the complementary exhibition area to the new Spitz Space Voyager Planetarium system and its multi-dimensional program capabilities. ASTRONOMY - HOW DO WE KNOW? will make the science of astronomy more accessible to the public by demonstrating the above objectives through the fundamental concepts of Gravity, Light, Motion and Distance. Visitors will leave with a greater understanding of the process of learning about the Universe. Discovery Place will utilize the formative evaluation process in developing these exhibits to assure a product that will not only appeal to a broad audience, but will also meet a variety of identified needs within that audience. The exhibit and program package will open in October, 1992, with an anticipated yearly attendance of 700,000. The exhibits will be a permanent part of the museum and will be renewed through the general operating budget of the museum.
The Anchorage Museum of History and Art will develop "Lifting the Fog: Russian Exploration in the North Pacific, 1728-1867." This exhibition will reveal the world of the naturalists, oceanographers, astronomers, cartographers, ethnographers and artists who first described the west coast of America and the northern Pacific Ocean to the world. Approximately 200,000 visitors to the museum will view the 5,300-sq. ft. exhibition. Public programs will complement the exhibition, including a family day, lecture series by marine biologists, living history programs, weekend workshops, and an international symposium. An illustrated catalog with interpretive essays and a school curriculum and teachers' guide will accompany the exhibition. The exhibition will travel to three additional venues in the United States.
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.
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 education project is a time sensitive opportunity related to the March 9, 2016 Total Solar Eclipse occurring in a remote part of the world located in Waleia in the Federated States of Micronesia, a U.S. affiliated Pacific Island nation. The path of totality is only 100 miles wide and passes through only a few Pacific Island nations ending in Hawaii. This project uses this unique phenomenon to educate a large US and international audience about solar science using multi-platforms with integrated video, social media, and public programs. Project deliverables include the production of a broadcast of the eclipse live from Waleia in the Federated States of Micronesia on March 9, 2016 making it accessible to hundreds of countries and millions of people around the world via satellite and live streaming on the Internet. Additional deliverables include on-site educational programs at science centers and planetariums as well as media resources for long-term use. These resources will enhance the interest and preparedness for additional public engagement when the 2017 eclipse occurs in the U.S. 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 solar physics research by funding the construction of the world's largest solar telescope, the Daniel K. Inouye Solar Telescope which is slated to begin operations in late 2019 and operated by the National Solar Observatory. This new facility will revolutionize researchers' capability to study the Sun and its magnetic fields. This education project leverages that investment 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 worldwide through the Internet.
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ExploratoriumRobert SemperNicole MinorRobyn Higdon
Nationally, there is tremendous interest in enhancing participation in science, technology, engineering, and mathematics (STEM). Providing rich opportunities for engagement in science and engineering practices may be key to developing a much larger cadre of young people who grow up interested in and pursue future STEM education and career options. One particularly powerful way to engage children in such exploration and playful experimentation may be through learning experiences that call for tinkering with real objects and tools to make and remake things. Tinkering is an important target for research and educational practice for at least two reasons: (1) tinkering experiences are frequently social, involving children interacting with educators and family members who can support STEM-relevant tinkering in various ways and (2) tinkering is more open-ended than many other kinds of building experiences (e.g., puzzles, making a model airplane), because it is the participants' own unique questions and objectives that guide the activity. Thus, tinkering provides a highly accessible point of entry into early STEM learning for children and families who do not all share the same backgrounds, circumstances, interests, and expertise. This Research-in-Service to Practice 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. The project will take place in the Tinkering Lab exhibit at Chicago Children's Museum. The research will investigate how reflective interactions between parents and children (ages 6-8) during tinkering activities ultimately impact child engagement in STEM. Design-based research (DBR) is well-suited to the iterative and contextually-rich process of tinkering. Using a DBR approach, researchers and museum facilitators will be trained to prompt variations of simple reflection strategies at different time points between family members as a way to strengthen children's engagement with, and memory of these shared tinkering events. Through progressive refinement, each cycle of testing will lead to new hypotheses that can be tested in the subsequent round of observations. The operationalization of study constructs and their measurement will come organically from families' activities in the Tinkering Lab and will be developed in consultation with members of the advisory board. Data collection strategies will include observation and interviews; a series of coding schemes will be used to make sense of the data. The research will result in theoretical and practical understanding of ways to enhance STEM engagement and learning by young children and their families through tinkering. A diverse group of at least 350 children and their families will be involved. The project will provide much needed empirical results on how to promote STEM engagement and learning in informal science education settings. It will yield useful information and resources for informal science learning practitioners, parents, and other educators who look to advance STEM learning opportunities for children. This research is being conducted through a partnership between researchers at Loyola University of Chicago and Northwestern University and museum staff and educators at the Chicago Children's Museum.
The range of contemporary "emerging" technologies with far-reaching implications for society (economic, social, ethical, etc.) is vast, encompassing such areas as bioengineering, robotics and artificial intelligence, genetics, neuro and cognitive sciences, and synthetic biology. The pace of development of these technologies is in full gear, where the need for public understanding, engagement and active participation in decision-making is great. The primary goal of this four-year project is to create, distribute and study a set of three integrated activities that involve current and enduring science-in-society themes, building on these themes as first presented in Mary Shelley's novel, Frankenstein, which will be celebrating in 2018 the 200th anniversary of its publication in 1818. The three public deliverables are: 1) an online digital museum with active co-creation and curation of its content by the public; 2) activities kits for table-top programming; and 3) a set of Making activities. The project will also produce professional development deliverables: workshops and associated materials to increase practitioners' capacity to engage multiple and diverse publics in science-in-society issues. The initiative 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. This project by Arizona State University and their museum and library collaborators around the country will examine the hypothesis that exposing publics to opportunities for interactive, creative, and extensive engagement within an integrated transmedia environment will foster their interest in science, technology, engineering and mathematics (STEM), develop their 21st century skills with digital tools, and increase their understanding, ability, and feelings of efficacy around issues in science-in-society. These three distinct yet interlocking modes of interaction provide opportunities for qualitative and quantitative, mixed-methods research on the potential of transmedia environments to increase the ability of publics to work individually and collectively to become interested in and involved with science-in-society issues.
This paper draws on ethnographic data to bring equity to the fore within discussions of tinkering and making. Vossoughi, Escudé, Kong & Hooper argue that equity lies in the how of teaching and learning through specific ways of: designing making environments, using pedagogical language, integrating students’ cultural and intellectual histories, and expanding the meanings and purposes of STEM learning. The authors identify and exemplify emergent equity-oriented design principles within the Tinkering After-School Program—a partnership between the Exploratorium and the Boys and Girls Clubs of San
Petrich, Wilkinson, and Bevan (2013) explore three areas of design principles related to tinkering. The authors share their thinking related to the activity design, environmental design, and facilitation practices involved in creating and supporting rich tinkering experiences for museumgoers. They wrote a chapter on tinkering, which describes how the group initiated, cultivated, and facilitated a making and tinkering space on the floor of a museum. Specifically the chapter outlines principles for the activity design, the tinkering space, and the facilitation practices. The authors conclude by
The overall objective of this planning project was to examine the potential effectiveness of the Signing Science Pictionary (SSP) in increasing the ability of parents and their deaf and hard of hearing children to engage in informal science learning. To achieve this objective, research and development included four goals. 1) Design several SSP-based activities to help family members engage in informal science learning. 2) Examine the potential effectiveness of the SSP in increasing family member’s signed science vocabulary. 3) Find out about the potential effectiveness of the SSP in
With NCRR SEPA Phase I funding, the Exploratorium developed a microscope imaging station (MIS) for public use in the museum. At this facility, visitors explore living things using research-grade equipment. For visitors, microscopes and images are engagement points for learning more about basic biology, biomedical research, and human health. With SEPA Phase II funding, the Exploratorium proposes to use the infrastructure and educational approach developed in Phase I to: (1) Create a wider, more comprehensive array of biomedically relevant, image-based materials-including still and time-lapse images, movies, and teaching activities; and (2) Disseminate these to students, teachers, museum visitors, the broader public, and other science centers. The Exploratorium will collaborate with biomedical researchers to generate high-resolution images and plan public programs. Material from these collaborations will be on current biomedical topics. Planned dissemination activities include eight "Meet the Scientist and Learn about Their Research" public programs; Saturday teacher workshops; development of multimedia exhibit content for museum display; development of web content for the MIS site; creation of image-based teacher activities; inclusion of images, movies, and activities in established web-based teacher resources (as well as new resources for high-bandwidth Internet2 application). Materials will be free to other educational institutions. Using these dissemination strategies, the Exploratorium expects to attract and engage well over 1 million visitors annually.
The Maker Movement has taken the educational field by storm due to its perceived potential as a driver of creativity, excitement, and innovation (Honey & Kanter, 2013; Martinez & Stager, 2013). Making is promoted as advancing entrepreneurship, developing science, technology, engineering, and mathematics (STEM) workforce, and supporting compelling inquiry-based learning experiences for young people. In this paper, we focus on making as an educative inquiry-based practice, and specifically tinkering as a branch of making that emphasizes creative, improvisational problem solving. STEM-rich