The National Science Festival Network project, also operating as the Science Festival Alliance, is designed to create a sustainable national network of science festivals that engages all facets of the general public in science learning. Science Festivals, clearly distinct from "science fairs", are community-wide activities engaging professional scientists and informal and K-12 educators targeting underrepresented segments of local communities historically underserved by formal or informal STEM educational activities. The initiative builds on previous work in other parts of the world (e.g. Europe, Australasia) and on recent efforts in the U.S. to create science festivals. The target audiences are families, children and youth ages 5-18, adults, professional scientists and educators in K-12 and informal science institutions, and underserved and underrepresented communities. Project partners include the MIT Museum in Cambridge, UC San Diego, UC San Francisco, and the Franklin Institute in Philadelphia. The deliverables include annual science festivals in these four cities supported by year-round related activities for K-12 and informal audiences, a partnership network, a web portal, and two national conferences. Ten science festivals will be convened in total over the 3 years of the project, each reaching 15,000 to 60,000 participants per year. STEM content includes earth and space science, oceanography, biological/biomedical science, bioinformatics, and computer, behavioral, aeronautical, nanotechnology, environmental, and nuclear science. An independent evaluator will systematically assess audience participation and perceptions, level/types of science interest stimulated in target groups, growth of partnering support at individual sites, and increasing interactions between ISE and formal K-12 education. A variety of qualitative and quantitative assessments will be designed and utilized. The project has the potential to transform public communication and understanding of science and increase the numbers of youth interested in pursuing science.
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TEAM MEMBERS:
Loren ThompsonJeremy BabendureBen Wiehe
In partnership with the University of Pennsylvania's Graduate School of Education, The Franklin Institute Science Museum will develop, test, and pilot an exportable and replicable cyberlearning exhibit using two cutting edge technologies: Augmented Reality (AR) and Virtual Reality (VR). The exhibit's conceptualization is anchored in the learning research vision of the NSF-funded workshop Cyberinfrastructure for Education and Learning for the Future (Computing Research Association, 2005). The incorporation of VR and AR technologies into the Franklin Institute's electricity and Earth science exhibits is an innovation of traditional approaches to hands-on learning and will improve the quality of the learning experience for the primary audience of families with children and elementary school groups. The project has implications for future exhibit development and more broadly, will provide new research on learning on how to incorporate cyberlearning efforts into traditional exhibits. Fifteen participating exhibit developers across the ISE field will assist in the evaluation of the new exhibit; receive training on the design and development of VR and AR exhibits for their institutions; and receive full access to the exhibit's new software for implementation at their informal learning sites. The technology applications will be developed by Carnegie Mellon University's Entertainment Technology Center--leaders in the field in Virtual Reality design and development. Front-end and formative evaluation will be overseen internally by the Franklin Institute. The Institute for Learning Innovation will conduct the summative evaluation. Research will be conducted by the University of Pennsylvania's Graduate School of Education on the effects of AR and VR technologies on exhibit learning.
In the Communities of Learning for Urban Environments and Science (CLUES) project, the four museums of the Philadelphia-Camden Informal Science Education Collaborative worked to build informal science education (ISE) capacity in historically underserved communities. The program offered comprehensive professional development (PD) to Apprentices from 8-11 community-based organizations (CBO), enabling them to develop and deliver hands-on family science workshops. Apprentices, in turn, trained Presenters from the CBOs to assist in delivering the workshops. Families attended CLUES events both at the museums and in their own communities. The events focused on environmental topics that are especially relevant to urban communities, including broad topics such as climate change and the energy cycle to more specific topics such as animals and habitats in urban neighborhoods.
The Coalition for Science After School (CSAS) was established in 2004 in response to the growing need for more STEM (science, technology, engineering, and mathematics) learning opportunities in out-of-school time. CSAS sought to build this field by uniting STEM education goals with out-of-school time opportunities and a focus on youth development. Over a decade of work, CSAS Steering Committee members, staff and partners advocated for STEM in out-of-school-time settings, convened leaders, and created resources to support this work. CSAS leadership decided to conclude CSAS operations in 2014, as the STEM in out-of-school time movement had experienced tremendous growth of programming and attention to science-related out-of-school time opportunities on a national level. In its ten-year strategic plan, CSAS took as its vision the full integration of the STEM education and out-of-school time communities to ensure that quality out-of-school time STEM opportunities became prevalent and available to learners nationwide. Key CSAS activities included: (1) Setting and advancing a collective agenda by working with members to identify gaps in the field, organizing others to create solutions that meet the needs, identifying policy needs in the field and supporting advocates to advance them; (2) Developing and linking committed communities by providing opportunities for focused networking and learning through conferences, webinars, and other outreach activities; and (3) Identifying, collecting, capturing, and sharing information and available research and resources in the field. The leadership of the Coalition for Science After School is deeply grateful to the funders, partners, supporters, and constituents that worked together to advance STEM in out-of-school time during the last decade, and that make up today's rich and varied STEM in out-of-school time landscape. We have much to be proud of, but as a movement there is much more work to be done. As this work continues to expand and deepen, it is appropriate for the Coalition for Science After School to step down as the many other organizations that have emerged over the last decade take on leadership for the critical work that remains to be done. A timeline and summary of CSAS activities, products, and accomplishments is available for download on this page. All resources noted in the narrative are also available for download below.
The Dynamic Earth: You Have To See it To Believe It is a public exhibition and suite of programming designed to educate and excite K-8 students, teachers, and families about weather and climate science, plate tectonics, erosion, and stream formation. The Dynamic Earth program draws attention to the importance of large-scale earth processes and the human impacts on these processes, utilizing real artifacts, hands-on models, and NASA earth imagery and data. The program includes the exhibition, student workshops, family workshops, annual professional development opportunities for classroom teachers, innovative theater shows, lectures for adults by visiting scientists, and interpretive activities. The Montshire Museum of Science has partnered with Chabot Space and Science Center (CA) and the US Army Corps of Engineers Cold Regions Research and Engineering Laboratory (NH) on various components. The project has broadened our internal capacity for providing quality earth science programming by greatly expanding our program titles and allowing us to create hands-on materials for use by our educators and to loan to schools in our Partnership Initiative. Programming developed during the grant period continues to reach thousands of students and teachers each year, both on-site and as part of our rural outreach efforts.
Exploring Ocean Science from Space (EOSS) is an integrated program of marine life exhibits and science programming designed to bring broader awareness of NASA’s ocean research and Science, Technology, Engineering and Mathematics (STEM) to our staff, volunteers, students, their families and teachers, as well as the visiting public. The Seattle Aquarium was the lead institution, and partnered with NASA and NOAA. The project’s goal to advance NASA’s commitment to share its research through informal education and helping more than 1.5 million people better understand the role of oceans in our earth system while they increase their STEM literacy has been achieved. The project created and implemented a wide range of programs and products including a teen intern program, interpretive programming, special events, Bering Sea Bingo educational game, hands-on activity kits including Wi-Fi enabled tablets to utilize online NASA content for interpretation, exhibit improvements to enhance the learners’ experience, electronic interactive stations, and a self-guided Aquarium workbook.
Backyard Mystery is an NSF-funded curriculum, focused on diseases, pathogens and careers, using interactive paper and physical activities. Content is for middle school participants in afterschool settings, like 4-H and other similar venues. The curriculum engages student interest in genetics and genomics and in the bioSTEM workforce. The curriculum storyline is placed in a familiar setting to students--the backyard--and explores fungi, bacteria, viruses and parasites in a way that is engaging fun and informative. It can be tailored to specific audiences, e.g. participants interested in animal science will gain from focusing on the parasite panel. The curriculum is available in two forms: a combined lesson that brings all of the elements together in one session and another in which the content is broken out into three separate lessons. We would like to share this curriculum with facilitators and educators for both out-of-school time and classroom settings. It is available electronically and free to use. We only ask for users to complete a brief survey to give us feedback, which is helpful for NSF.
The Oregon Museum of Science and Industry (OMSI) will create a 5,000 sq ft traveling exhibition designed to engage families with children ages 10-14 with concepts of algebra. Access Algebra will increase visitor awareness of the role of algebra in everyday life and help them to develop algebraic thinking skills. This exhibition will travel to 21 science centers, reaching some 3.5 million visitors on its national tour. It will be accompanied by an Educator's Guide, Family Guide, and complementary web activities. Access Algebra incorporates testing and implementation of an innovative model for professional development for museum exhibit, program, and interpretive staff. It links the exhibition tour to training at each venue designed to increase knowledge of algebra concepts and to develop facilitation skills in family math learning. The package includes workshops, training DVD, printed guide, Math Toolkit, and website support. Project partners include TERC, Oregon State University College of Education (OSU), and Blazer Boys & Girls Club (BBGC). The BBGC members will participate in exhibit development over an extended (12-week) period, helping to create an exhibition that will engage a target audience of underserved low-income youth. The strategic impact of Access Algebra derives from the development and testing of effective strategies for engaging audiences in exhibit-based informal math learning, along with increasing the capacity of the field for facilitating these kinds of experiences through a new model for professional development.
The New England Wild Flower Society, in collaboration with the Yale Peabody Museum, Montshire Museum of Science, and the Chewonki Foundation, is implementing the Go-Botany project, a multi-faceted, web-based botany user interface. "Go-Botany: Integrated Tools to Advance Botanical Learning," improves botanical education by opening plant study to a larger and more diverse segment of the population including novices, citizen scientists, and informal science educators. The project is designed to integrate a variety of web tools and mobile communication devices to facilitate learning about botany and plant conservation with a focus on native and naturalized plants in New England. Project deliverables include an online database of New England plants; online keys to over 4,000 species of New England flora; a customizable user interface; My Plants personal webpages; an outdoor exhibit that incorporates mobile resources; training programs for informal science educators and educational programs for the public. Projected impacts include increased attraction to and engagement in botanical learning for public audiences and improved teaching abilities by informal science education professionals through the application of user friendly, digital resources on mobile communication devices. Go-Botany significantly impacts the field of informal science education by changing the way that informal learners learn about plants by removing barriers through the use of free online materials, mentoring, and user created resources. This project is projected to reach over 46,000 youth, adults, and informal educators in workshops and via the Go-Botany website.
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TEAM MEMBERS:
Elizabeth FarnsworthGregory LowenbergArthur HainesWilliam Brumback
This collaboration between the Franklin Institute and the Free Library of Philadelphia Foundation identifies the role of crucial intermediaries in the science learning of children and points to the opportunities offered through a museum and library partnership to provide engaging science resources in under-resourced communities where many adults lack science expertise and confidence. Through an emphasis on literacy and science, LEAP into Science builds the capacity of after school leaders, teens and parents to be competent science learners and facilitators and to connect science centers, parents and libraries in support of the science learning and achievement of children. Project features include a workshop model for families with K-4 children, enrichment sessions for after school students, family events at the museum, professional development for library and after school youth staff, and a national expansion conference. The conference introduces the project to potential national implementation sites. Case studies of sites from this conference inform a research study investigating the obstacles, modifications and necessary support to initiate and sustain the program model. The formative and summative evaluation measure the impact of this program on children, parents, librarians, and teen workers at the libraries. Fifty-three Philadelphia libraries in addition to libraries in three cities selected from the implementation conference have a direct program impact on 10,000 people nationally, including 300 after school facilitators and children's librarians.
Michigan Technological University will collaborate with David Heil and Associates to implement the Family Engineering Program, working in conjunction with student chapters of engineering societies such as the American Society for Engineering Education (ASEE), the Society of Hispanic Professionals (SHP) and a host of youth and community organizations. The Family Engineering Program is designed to increase technological literacy by introducing children ages 5-12 and their parents/caregivers to the field of engineering using the principles of design. The project will reach socio-economically diverse audiences in the upper peninsula of Michigan including Native American, Hispanic, Asian, and African American families. The secondary audience includes university STEM majors, informal science educators, and STEM professionals that are trained to deliver the program to families. A well-researched five step engineering design process utilized in the school-based Engineering is Elementary curriculum will be incorporated into mini design challenges and activities based in a variety of fields such as agricultural, chemical, environmental, and biomedical engineering. Deliverables include the Family Engineering event model, Family Engineering Activity Guide, Family Engineering Nights, project website, and facilitator training workshops. The activity guide will be pilot tested, field tested, and disseminated for use in urban, suburban, and rural settings. Strategic impact will result from the development of content-rich engineering activities for families and the dissemination of a project model that incorporates the expertise of engineering and educational professionals at multiple levels of implementation. It is anticipated that 300 facilitators and 7,000-10,000 parents and children will be directly impacted by this effort, while facilitator training may result in more than 27,000 program participants.
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TEAM MEMBERS:
Neil HutzlerEric IversenChristine CunninghamJoan ChaddeDavid Heil
This project will introduce students ages 8-14, including underserved students; their teachers and families; and the general public to three biomedical research areas inspired by NIH's Roadmap for Medical Research: biological pathways, bioinformatics and nanomedicine. These areas are unfamiliar to many adults and are not introduced in science curricula. Using the metaphor of a hardware store (i.e., building materials, tools, parts, home repair projects), the project will introduce families, students and teachers to three ideas: (1) The body maintains and repairs itself at the molecular, cell, tissue, organ and system levels; (2) Biomedical researchers are uncovering new complexities at the molecular level that can increase our understanding of how the body works; and (3) Developments in nanomedicine can lead to discoveries and treatments. In a hardware store theater and workshop space and in a virtual hardware store, the project will develop and present demonstrations and basic- and intermediate-level labs (for 2nd- and 6th-grade students or families); train museum staff and interns to present the programs; offer orientation workshops to teachers from Title I schools; develop a teacher's guide; conduct outreach in middle schools; engage scientists to talk about their work and help them communicate with the public; and create a manual of materials and activities for other science centers. The evaluation plan will include formative research on activities and assessment of how well repair metaphors facilitate understanding of clinical issues. A team of scientists, museum staff, science teachers, and biology and medical students will guide the development of education components.