The Museum of Science and Industry in Tampa, Florida, will develop a permanent exhibition and associated educational programs on natural hazards, phenomena that become "natural disasters" when they interact with the human community and its built environment. The exhibition, 9000 square feet in size, will address the science of these phenomena, the science and technology of forecasting and mitigation strategies and techniques. The exhibition features floods, hurricanes, wildfires, lightning, hail, tornadoes, earthquakes and volcanoes. The exhibition begins with an overview and a focus on the dynamic earth. It then presents a streetscape of buildings devastated by the phenomena and eight interactive areas dealing with each of the hazards. The concluding sections include a demonstration stage and a series of elements that focus on communications, community preparedness and response and forecasting. Ancillary materials include: a family exhibition guide, teacher preparation materials, classroom materials on forecasting, a distance learning program and a brochure for the public (to be developed by IBHS). Central to the project is MOSI's partnership and campus neighbor, Institute for Business and Home Safety, a nonprofit arm of the insurance industry with a mandate to educating Americans about natural disasters and ways to mitigate loss and suffering. Other partners include FEMA, USGS, Red Cross, NFPA, local schools and community based organizations. The Institute for Learning Innovation will conduct the evaluation, supplemented by action research investigations by the University of South Florida. A local high school emphasizing design and art will participate in the exhibition development process.
Seeing in the Dark will be a prime-time PBS special about stargazing -- described in the proposal as "the interaction between starlight and human beings who have a look for the love of it, whether just learning the constellations or doing amateur astronomy so advanced that it sometimes rivals professional research." The project teaches "hands-on" astronomy drawing heavily on new technology (large, inexpensive "Dobsonian" telescopes; charged-coupled light-sensing devices [CCDs}; and the Internet) that make astronomical observing practical for millions to whom it has previously been at best a remote possibility. The video will be supported by an extensive outreach effort that includes informal, family projects and formal, in-class exercises. The Astronomical Society of the Pacific will be a major outreach partner. There also is a companion book, "Seeing in the Dark," published by Simon & Schuster.
The Ocean Institute will design, develop, evaluate and install "Sea Floor Science," a 5,200 sq. ft. site-wide exhibition designed in partnership with Scripps Institution of Oceanography, the Jet Propulsion Laboratory, and the Institute of Nautical Archaeology at Texas A&M University. "Sea Floor Science" will provide opportunities for families, students and the general public to use authentic oceanographic equipment, tools and technology to recreate a world of ocean research and discovery. Visitors will experience how oceanographers are exploring the largely unknown sea floor to permit better understanding of the origin of sediments and rocks, paleoclimate reconstruction as evidenced by marine microfossils, and the dynamics of oceanic lithospheres and margins. The project is a new approach to museum exhibits. It will test innovative convertibility solutions that enable public areas to serve as both teaching stations and effective exhibits. It will also implement cost-effective update strategies to keep visitors at the forefront of scientific research. "Sea Floor Science" will reach 4,000,000 people in 22 states including on-site and on-line visitors, multi-state teacher networks, videoconferencing participants, science professionals, and replication sites at science centers and aquaria nationally.
Building on an institution-wide strategic initiative to interpret the process of science for informal learners of all ages, the Museum of Science will work over four years to develop, evaluate and implement a project to communicate the processes of science through weather forecasting. The project is based on the idea that processes involved in short-term weather forecasting are basic to the process of science. MOS proposes to create a 1,800 square foot exhibit, programs for students and teachers, an interactive website, and one-minute television spots aimed at helping people understand weather forecasting. The project is grounded in MOS strategic commitment to engaging people in the activity of science and the use of new technologies. The major component of the project is an exhibition of weather in which visitors will learn how to forecast the weather over the next few hours using different levels of technology, including naked eye observations, data from weather maps, and real-time images from space satellites and ground radar stations. Ancillary programs include educational materials for over 100 WeatherNet schools in New England, an interactive website that will reach several hundred thousand users, and television spots on the process of weather forecasting to be aired on WBZ-TV Channel 4. Over the course of its life the project will engage several million children and adults in the process of science.
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TEAM MEMBERS:
Cary SneiderMishelle MichaelsDaniel Barstow
The Lawrence Hall of Science at the University of California at Berkeley will develop the "Real Astronomy Experience (RAE)" in which science center visitors will explore the universe by controlling and viewing robotic telescopes via the Internet; by using image processing software to understand the images they capture; and by capturing images with a hands-on, functional telescope equipped with a Charge-Coupled Device (CCD) camera to learn how a modern telescope image-capture system works. Guided by project materials, visitors learn about the cosmos, tools and methods of scientific research, data analysis and the general progress of modern astrophysics.
Waves in Space, an educational museum exhibit for upper elementary and middle school students, clarifies the concept of radio wave propagation and how it is affected by variations in the Earth's atmosphere. The exhibit is based on research in upper atmospheric physics conducted by the Atmospheric Sciences Group at the MIT Haystack Observatory. This research is at the forefront of the emerging national space weather effort, a large NSF initiative to forecast and predict dynamic conditions in Earth's upper atmosphere and the effects these conditions have on key technologies such as cellular phones, pagers and satellites.
The Anchorage Museum of History and Art, working with the Calista Elders Council, will develop a 5,000 sq ft traveling exhibition presenting 19th-century Yup'ik Eskimo technologies, their contemporary applications, and the underlying scientific processes. Featuring Yup'ik artifacts, it will integrate indigenous knowledge into the teaching of basic science principles as well as demonstrate the role played by science in everyday life. The exhibition will be organized around seasonal activities practiced in the past and retaining modern relevance. The Oregon Museum of Science and Industry (OMSI) will develop the comparative exhibits on modern science and technology, and the Imaginarium will develop complementary educational programming. Primary audiences will include rural Alaska Natives, both youth and elders, non-Native Alaska residents and visitors, as well as venues outside Alaska. By demonstrating how indigenous knowledge can be related to modern science, this exhibition provides a model for the informal science education field on how to incorporate cultural aspects of their own communities into museum exhibitions and programs. In addition, it demonstrates how artifacts and hands-on science activities can be combined effectively to create engaging educational experiences.
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.
This project continues the development, testing, and use of a series of web-based computer simulations for improving the teaching and learning of physics. It expands the number of simulations in physics, creates new simulations addressing introductory chemistry, creates simulations addressing the conceptual understanding of equations in solving science problems, and further refines some existing simulations. It increases, by approximately 35, the 35 online interactive simulations that have been developed for teaching physics. The project produces and widely disseminates on-line supporting materials for use in undergraduate and high school science courses. The supporting materials include: guided-discovery, tutorial worksheets; a list of learning goals; materials to support in-lecture, homework, and laboratory use; assessment instruments; and other user-contributed materials. The simulations being introduced and their effectiveness are being evaluated in at least eight additional courses in physics and chemistry at the University of Colorado and a diverse set of partner institutions. The materials are being extensively tested to ensure that they are easy to use and effective at promoting deep conceptual understanding and positive attitudes about science and technology.
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TEAM MEMBERS:
Carl WiemanNoah FinkelsteinKatherine Perkins