In 1988 and 1989, ASTC offered a seven-day institute for founders of new science centers, funded by the National Science Foundation. The impact of these institutes was profound, making the difference between success and failure for several, and helping many others clarify and strengthen their plans. Since then demand for technical assistance to new science centers has increased rather than decreased. Building on its experience, ASTC proposes a 3-1/2 year multiple-strategy program to provide knowledgeable, supportive guidance to the founders of new science centers. The elements are: (1) a 4-day workshop on how to start a science center; (2) a resource book on starting and operating science centers; (3) a network for new science centers which meets at the ASTC annual conference for mutual support and information sharing; (4) one-day workshops held in Conjunction with the ASTC conference and planned by the steering committee of the New Science Center Network; (5) increased coverage in the ASTC Newsletter; (6) an annual progress report on new science centers; and (7) on-going, individualized technical assistance.
The Buffalo Society of Natural Sciences plans to conduct a 5 year project to train 150 mentor teachers (30 teachers/year) and their principals, who will then train the remaining 1100 elementary teachers in the Buffalo Public School System. The training would include two 5-week summer sessions (in a Magnet school that is physically incorporated into the Buffalo Museum of Science) and 4 in-service workshops during the academic years following each of the summer workshops. This innovative leadership project is a collaborative effort between the Buffalo Society of Natural Sciences (including both education and curatorial/science staff persons) the Buffalo Public Schools, and individuals from local colleges and universities. The setting of the project is enhanced by a Science and Math Magnet School which is housed within the museum, and by the school/museum's location in a largely inner city environment with easy accessibility to minority persons. The project is designed to provide mentor teachers with a strong science background in pedagogy and content over a two-year period of summer and academic-year workshops, and to prepare and support these mentors as they inservice their colleagues. Project staff from the museum, public schools, and the academic community will provide strong support through academic-year workshops, site visits and telecommunications networking. Principals will be appropriately involved, and will work with mentors to develop a science inservice program tailored to meet the needs of their individual schools; as a consequence, virtually all of the 1100 K-6 classroom teachers of science in the Buffalo Public Schools will have been prepared to teach investigative, hands-on science to their students. Non-NSF cost sharing is approximately 27.9% of the amount requested from NSF.
The objective of this project is to provide a complete package of KIDSPACE hands-on science experiences to small and developing science centers across the country through the National KIDSPACE Partnership Program. This project will allow twelve (12) selected science centers to implement a complete, proven education package geared toward young children at a fraction of the cost of starting one from scratch. This project will provide comprehensive training to a large core of educators within the science center field, and will support continued research into the informal science education of young children through an original Research Study and the formation of a national User's Group. Best of all, this project will generate a wellspring of invaluable science-play connections for hundreds of thousands of children to tale with them into adulthood.
The American Association for the Advancement of Science, in collaboration with the Association of Science-Technology Centers and several science centers, has requested $837,958 in NSF support of a project to make science museums more accessible to minority groups. In the project, AAAS and ASTC propose to provide technical assistance and staff training to science museums on equity issues, with emphases on institutional self- assessment, developing effective science education programs reaching minority audiences, and working effectively with community organizations and other institutions serving minority groups. Several museum sites will be involved initially in the development of the four program components: 1. development of guidelines for an equity self-assessment in museums; 2. science equity training for all museum staff; 3. the development of relationships between museums and community groups and schools and colleges and universities that serve minorities; and 4. a national effort to create awareness among minority groups of employment opportunities in science museums. Additional dissemination will be provided through training workshops and sessions at museum conferences. A "how-to" guide and video will be developed for museums on conducting an equity self-assessment.
The Franklin Institute Science Museum will develop, install and evaluate a museum-wide Interactive Computer Information System (ICIS) designed to enhance visitors' exhibit learning through museum-wide visitor information access and connectivity. ICIS will provide educational experiences for 1.2 million people per year, tailoring its information presentations to individual visitor needs and levels of knowledge. Exhibit based units will add advanced presentation functions beyond the usual graphics and text labels. ICIS will include 67 touchscreen-operated computer stations and six min- computers linking 27 exhibit areas in The Franklin Institute. This project is a collaboration between The Franklin Institute and the Unisys Corporation, which will provide over a five year period systems engineering, hardware, installation, maintenance and training of museum personnel valued at $2.4 million. An extensive evaluation plan will include studies of visitor-computer interaction, the economics and management of system maintenance, collaboration between museum and corporation and effectiveness of computer-based exhibit interpretation techniques. Project results will be disseminated through conference presentations, seminars and published articles.
The National Zoological Park, a component of the Smithsonian Institution, proposes transforming three traditional zoo exhibit buildings into centers for informal science learning. Based on current knowledge about learning, the proposed project will feature interactive elements as well as the greater use of human interpreters to help visitors examine animals, handle objects and play games. The project is to be a collaborative effort by the National Zoological Park, the Dallas Zoo and Zoo Atlanta, with the National Zoo developing the materials and making and shipping copies to Dallas and Atlanta as centers for tryout and evaluation, with the results of the studies going to other zoos in way of encouraging them of the importance of interactive science education.
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TEAM MEMBERS:
Judith WhiteJames MurphyDale MarcelliniJeffrey Swanagan
resourceprojectProfessional Development, Conferences, and Networks
Informal learning in math, science, and technology is an increasingly important vehicle for educating the public. Throughout their lifetime, the average citizen will spend a much greater amount of time in informal learning environments than in school. For these efforts to continue without benefit of understanding, the dynamics of what makes informal learning experiences work, is a waste of valuable funding resources. Research Communications Ltd. (RCL) proposes an effort to investigate what has been learned about informal learning in math, science, and technology and to develop some directions for future research in this important area. The first step in the process would be to review the existing literature in the three primary areas of informal education for math, science, and technology: television/radio, community projects, and science museums and technology centers with a focus on evaluation studies that have shown what strategies have worked and those that have not. The outcome of this effort would be a comprehensive publication of what is currently known about informal learning research in math, science and technology.
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TEAM MEMBERS:
Valerie CraneTom Birk
resourceprojectProfessional Development, Conferences, and Networks
This project is aimed at perfecting and testing a new instructional method to improve the effectiveness of introductory physics teaching. the methods has two chief characteristics: 1) a systematic challenge to common sense misconceptions about the physical world, and 2) an emphasis on models and modeling as basic to physical understanding. Two versions of the method will be tested. The first version is designed especially for high school physics. It emphasizes student development of explicit models to interpret laboratory activities. After an initial test, this version will be taught to high school physics teachers in a summer Teacher Enhancement Workshop, and its effect on their subsequent teaching will be evaluated. Teachers with weak as well as strong backgrounds will be included. A special effort will be made to include females and minorities. The second version will be tested in a special college physics course designed to prepare students with weak backgrounds for a standard calculus based physics course. It emphasizes modeling techniques in problem solving. This project is jointly supported by the Division of Materials development, Research and Informal Science Education and the Division of Teacher Preparation and Enhancement.
Hands-On Science Outreach, Inc. has for a number of years developed and operated recreational after school and Saturday Science Classes for children, at first in Montgomery County, MD; and subsequently, with NSF support, at more than 22 sites around the country. During the last 10 years, they have reached more than 20,000 students with their unique collection of hands-on science activities. The project is well on the way to becoming self sufficient, and this final award will document both the philosophy of instruction and specific teaching methods that they have used and provide a third party evaluation of the processes of learning that they encourage in informal science education programs. Hands-On Science Outreach, Inc. will publish two 32 page booklets outlining their history, philosophy, and methods, and will conduct a third party evaluation of classes in four demographically diverse sites around the country, carried out under the direction of Dr. Harris Shettel, a nationally recognized informal education researcher. The resulting reports and publications will be widely disseminated, providing valuable information to others planning to offer hands-on science activities for children.
Scientists and engineers are an underutilized resource in motivating students and assisting classroom teachers in teaching science. Pilot programs have demonstrated the value of preparing scientists for what to expect when they enter the classroom, how to incorporate the school curriculum into their program, and how best to reach the goal of making their visits a "never to be forgotten" life changing experience for students. The concept of a Survival Kit is an outgrowth of a Scientist-in-Residence program at the North Carolina Museum of Life and Science which has successfully matched scientists and public school classrooms locally since 1982. The North Carolina Museum of Life and Science proposes to conduct meetings for staff and outside educational specialists to identify the materials and strategies needed to prepare scientists to enter school classrooms. The final report of these meetings will include mechanicals of a Scientist Survival Kit, which can be disseminated across the country, and an evaluation report of how the kits can be and are used. Dr. Mark St. John, Inverness Associates, a professional evaluator noted for his work with nationally significant science education projects, will provide local and national evaluation through surveys and meetings to give a picture of the issues involved in establishing and maintaining programs of scientists in the schools and the role played by the Scientist's Survival Kit in furthering this aim.
The middle-school and high-school years are a period of change and crystalization in terms of life goals, disciplinary and course preferences, and social and political attitudes. The literature provides a number of cross-sectional descriptions and models concerning cognitive and attitudinal development during adolescence and young adulthood, but there are no longitudinal data available to study these processes. The proposed longitudinal study will examine the (1) development of interest in science and mathematics, (2) the growth of scientific literacy, (3) the development of attentiveness to science and technology issues, and (4) the attraction to careers in science and engineering among two national cohorts of adolescents and young adults. One cohort will begin with a national sample of 3,000 seventh graders and follow them through the 10th grade. The second cohort will begin with a national sample of 3,000 10th graders and follow them for the next four years through the first full year after high school. Data will be collected from students, teachers, counselors, principals, and parents. A purposive sample of two or three school districts with exemplary elementary school science and mathematics education programs will be selected and comparable data will be collected in these districts. The analysis will consist of a series of expanding multivariate developmental models that will seek to understand cognitive and attitudinal growth and change in the context of family, school, and peer influences. Each wave of data collection will provide an opportunity to examine cognitive and attitudinal change measures in an increasingly rich context of previous measures. Periodic reports will be issued with each cycle of data collection and the data will be made available to other scholars on a timely basis. The first phase of the project, being funded at this time, provides approximately 15 months for instrument development and pilot testing, for sample selection, for monitor selection and training, and for working with the research advisory committee.
Project Enhanced Science Learning (PESL) offers learning partners opportunities to engage in authentic scientific inquiry through apprenticeship. Such inquiry is often enabled by dynamic interactions among learning partners in physical proximity. Yet scientific and business practice using Internet and broadband services recognizes that not all partners necessary to an interaction can be co-located. Our vision uses new technologies to extend the collaborative "reach" of PESL to include diverse expertise among remote learners, teachers, and scientists. This work, in atmospheric sciences, extends collaborative media beyond asynchronous text-only email to shared workspaces and two-way audio/video connections that allow for collaborative visualization of science phenomena, data, models - What You See Is What I See (WYSIWIS). Tools for local- and wide-area networked learning environments will enable highly interactive, media-rich communications among learning partners. Research on these learning architectures will provide pedagogy and social protocols for authenticating the science learning experience in classrooms and other spaces. Greater motivation to learn and enhanced science learning in terms of more valid, performance assessments should result from students' participations. The next decade brings widespread, networked multi-media interpersonal computing. This project will provide a blueprint to inform the effective use of interpersonal collaborative media for science education.