The Maker Program Blueprint offers a template for afterschool or summer programs and addresses the types of spaces that can be used, ideas about schedules and format, and the materials and personnel needed to create and sustain a program.
In January 2012, New York Hall of Science (NYSCI) hosted Design-Make-Play: Growing the Next Generation of Science Innovators. The two-day conference brought together leaders of schools, community-based programs, research and development organizations, the funding community, universities, government and business. They gathered at NYSCI to assemble evidence supporting the belief that designing, making and playing can create new pathways into science, technology, engineering and math (STEM), particularly among children. A core argument of Design-Make-Play is that informal learning centers like
Recognizing that the Maker movement embodies aspects of science, technology, engineering, and mathematics (STEM) learning that are the hallmarks of effective education — deep engagement with content, critical thinking, problem solving, collaboration, learning to learn, and more — NYSCI, in collaboration with Dale Dougherty and Tom Kalil, approached the National Science Foundation to sponsor a two-day workshop. Over 80 leaders in education, science, technology and the arts came together at NYSCI to consider how the Maker movement can help stimulate innovation in formal and informal education
What makes “making”—the next generation of inventing and do-it-yourself—worth paying attention to? In this report, we explore the three categories of makers, the ecosystem growing around those categories, the role technology plays in this ecosystem, and, finally, how business can take advantage of the opportunities this movement represents.
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TEAM MEMBERS:
John HagelJohn Seely BrownDleesha Kulasooriya
A team from Michigan State University, in partnership with six science, art-science, and art museum venues around the country and with the assistance of researchers at Georgia Institute of Technology, is implementing an EAGER project to conduct ongoing experiments on the chemical precursors to life as exhibit experiences for visitors to these venues. The experiments, to be run over the course of several months as the exhibit travels around the country, expand on the 1950s' work of Stanley Miller and Harold Urey, which continues to stimulate new investigations and publications, including experiments being conducted on the International Space Station. The experiments/exhibits share key features across the three different kinds of venues, allowing the team to study and compare the impacts on the various publics of engaging them in real-time science experiments. Two major goals are (1) to explore new ways to attract public interest in science by performing in public settings previously untried experiments on the chemical precursors to life, and (2) to investigate how the context of different kinds of venues and their visitor characteristics affect how visitors interpret the experience and what they learn. The team is also exploring how various data visualization representations can be designed to foster public interest and understanding. The intent is to develop an approach that has potential applications to other STEM content domains and expanding the reach to broader public audiences.
The goal of this project is to advance STEM education in Hawaii by creating a series of educational products, based on NASA Earth Systems Science, for students (grades 3-5) and general public. Bishop Museum (Honolulu HI) is the lead institution. NASA Goddard Space Flight Center is the primary NASA center involved in the project. Partners include Hawaii Department of Education and a volunteer advisory board. The evaluation team includes Doris Ash Associates (UC Santa Cruz) and Wendy Meluch of Visitor Studies Inc. Key to this project: the NASA STEM Cohort, a team of six current classroom teachers whom the Museum will hire. The cohort will not only develop curricula on NASA earth science systems but also provide guidance to Bishop Museum on creating museum educational programming that best meets the needs of teachers and students. The overall goal of Celestial Islands is to advance STEM education in Hawaii through the use of NASA Earth Science Systems content. Products include: 1) combined digital planetarium/Science on a Sphere® program; 2) traveling version of that program, using a digital planetarium and Magic Planet; 3) curricula; 4) new exhibit at Bishop Museum on NASA ESS; 5) 24 teacher workshops to distribute curricula; 6) 12 community science events. The project's target audience is teachers and students in grades 3-5. Secondary audiences include families and other members of the general public. A total of 545,000 people will be served, including at least 44,000 students.
The Global Soundscapes! Big Data, Big Screens, Open Ears Project uses the new science of soundscape ecology to design a variety of informal science learning experiences that engage participants through acoustic discovery Soundscape ecology is an interdisciplinary science that studies how humans relate to place through sound and how humans influence the environment through the alteration of natural sound composition. The project includes: (1) an interface to the NSF-funded Global Sustainable Soundscapes Network, which includes 12 universities around the world; (2) sound-based learning experiences targeting middle-school students (grades 5-8), visually impaired and urban students, and the general public; and (3) professional development for informal science educators. Project educational components include: the first interactive, sound-based digital theater experience; hands-on Your Ecosystem Listening Labs (YELLS), a 1-2 day program for school classes and out-of school groups; a soundscape database that will assist researchers in developing a soundscape Big Database; and iListen, a virtual online portal for learning and discovery about soundscape. The project team includes Purdue-based researchers involved in soundscape and other ecological research; Foxfire Interactive, an award-winning educational media company; science museum partners with digital theaters; the National Audubon Society and its national network of field stations; the Perkins School for the Blind; and Multimedia Research (as the external evaluator).
This award continues funding of a Center to conduct research and education on the interactions of nanomaterials with living systems and with the abiotic environment. The goals of this Center are to develop a predictive understanding of biological and ecological toxicology for nanomaterials, and of their transport and transformation in the environment. This Center engages a highly interdisciplinary, multi-institutional team in an integrated research program to determine how the physical and chemical properties of nanomaterials determine their environmental impacts from the cellular scale to that of entire ecosystems. The research approach promises to be transformative to the science of ecotoxicology by combining high throughput screening assays with computational and physiological modeling to predict impacts at higher levels of biological organization. The Center will unite the fields of engineering, chemistry, physics, materials science, cell biology, ecology, toxicology, computer modeling, and risk assessment to establish the foundations of a new scientific discipline: environmental nanotoxicology. Research on nanomaterials and development of nanotechnology is expanding rapidly and producing discoveries that promise to benefit the nation?s economy, and improve our ability to live sustainably on earth. There is now a critical need to reduce uncertainty about the possible negative consequences of nanomaterials in the environment, while at the same time providing guidelines for their safe design to prevent environmental and toxicological hazards. This Center addresses this societal need by developing a scientific framework of risk prediction that is paradigm-shifting in its potential to keep pace with the commercial expansion of nanotechnology. Another impact of the Center will be development of human resources for the academic community, industry and government by training the next generation of nano-scale scientists, engineers, and regulators to anticipate and mitigate potential future environmental hazards of nanotechnology. Partnerships with other centers will act as powerful portals for the dissemination and integration of research findings to the scientific, educational, and industrial communities, both nationally and internationally. This Center will contribute to a network of nanotechnology centers that serve the national needs and expand representation and access to this research and knowledge network through programs directed at California colleges serving underrepresented groups. Outreach activities, including a journalist-scientist communication program, will serve to inform both experts and the public at large about the safety issues surrounding nanotechnology and how to safely produce, use, and dispose of nanomaterials.
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TEAM MEMBERS:
Andre NelYoram CohenHilary GodwinArturo KellerPatricia Holden
Techbridge has proposed a broad implementation project that will scale up a tested multi-faceted model that increases girls' interest in STEM careers. The objectives of this project are to increase girls' engineering, technology, and science skills and career interests; build STEM capacity and sustainability across communities; enhance STEM and career exploration for underrepresented girls and their families; and advance research on the scale-up, sustainability, and impact of the model with career exploration. The Techbridge approach is grounded in Eccles' expectancy value model, and helps bridge critical junctures as girls transition from elementary to middle school and middle school to high school, immersing participants in a network of peers and supportive adults. Techbridge targets girls in grades 5-12 with a model that includes five components: a previously tested and evaluated curriculum, career exploration, professional development for staff and teachers, family engagement, and dissemination. The inquiry-based curriculum introduces electrical engineering and computer science through engaging, hands-on units on Cars and Engines, Green Design, and Electrical Engineering. The Techbridge model will be enhanced to include a central repository for curriculum and support materials, electronic girl-driven career exploration resources, an online learning community and video tools for staff, and customized family guides. Project deliverables include the dissemination of the enhanced model to three cities, 24 school sites and teachers, 2,000 girls, and over 600 role models. A supplementary research component will study the broad implementation of the Techbridge model by examining the fidelity of implementation and the program's impact on girls' STEM engagement and learning. The research questions are as follows: (1) To what extent and how do new program sites demonstrate adherence to the Techbridge program model? (2) Do new sites experience similar or increased participant responsiveness to Techbridge programming with regard to scientific learning outcomes, career awareness, attitude and interest in engineering? (3)How are changes experienced by girls sustained over time, if at all? (4) To what extent and how do new sites balance instilling the Techbridge essentials, those critical components Techbridge identifies as essential for success, with the need for local adaptation and ownership of the program? and (5) Given the potential for customization in local communities, do new sites maintain programmatic quality of delivery experienced at the original site? If so, what are elements essential to success regarding quality delivery? The mixed-methods study will include document analysis, embedded assessments, participant survey scales, and observations. Qualitative data methods include interviews with teachers, role models, staff and focus groups with girls. A project evaluation will also be conducted which investigates project outcomes for participants (girls, teachers, role models, and families) and fidelity of the implementation and enhancements at expansion sites, using a quasi-experimental approach. Career and learning outcomes for girls will be determined using embedded assessments, portfolios, surveys, school data, and previously validated instruments such as the Career Interest Questionnaire and the Modified Attitudes towards Science Inventory. The Managing Complex Change model is used as a framework for the project evaluation for the purpose of examining factors related to the effectiveness of scaling. The dissemination of research and evaluation findings will be achieved through the use of publications, blogs, social media, and conferences. It is anticipated that this project will broaden the participation of Hispanic, African-American, and English language learner girls, build capacity for STEM programming and sustainability at the dissemination sites, and disseminate findings to over 1 million educators, researchers, and community members. Broader impacts include contributing to the field's understanding of how virtual role models and field trips can engage young women, increase corporate advocacy, and engage participants in research and dissemination efforts.
The National Federation of the Blind (NFB), with six science centers across the U.S., will develop, implement, and evaluate the National Center for Blind Youth in Science (NCBYS), a three-year full-scale development project to increase informal learning opportunities for blind youth in STEM. Through partnerships and companion research, the NCBYS will lead to greater capacity to engage the blind in informal STEM learning. The NCBYS confronts a critical area of need in STEM education, and a priority for the AISL program: the underrepresentation of people with disabilities in STEM. Educators are often unaware of methods to deliver STEM concepts to blind students, and students do not have the experience with which to advocate for accommodations. Many parents of blind students are ill-equipped to provide support or request accessible STEM adaptations. The NCBYS will expose blind youth to non-visual methods that facilitate their involvement in STEM; introduce science centers to additional non-visual methods that facilitate the involvement of the blind in their exhibits; educate parents as to their students' ability to be independent both inside and outside the STEM classroom; provide preservice teachers of blind students with hands-on experience with blind students in STEM; and conduct research to inform a field that is lacking in published material. The NCBYS will a) conduct six regional, two-day science programs for a total of 180 blind youth, one day taking place at a local science center; b) conduct concurrent onsite parent training sessions; c) incorporate preservice teachers of blind students in hands-on activities; and d) perform separate, week-long, advanced-study residential programs for 60 blind high school juniors and seniors focused on the design process and preparation for post-secondary STEM education. The NCBYS will advance knowledge and understanding in informal settings, particularly as they pertain to the underrepresented disability demographic; but it is also expected that benefits realized from the program will translate to formal arenas. The proposed team represents the varied fields that the project seeks to inform, and holds expertise in blindness education, STEM education, museum education, parent outreach, teacher training, disability research, and project management. The initiative is a unique opportunity for science centers and the disability population to collaborate for mutual benefit, with lasting implications in informal STEM delivery, parent engagement, and teacher training. It is also an innovative approach to inspiring problem-solving skills in blind high school students through the design process. A panel of experts in various STEM fields will inform content development. NCBYS advances the discovery and understanding of STEM learning for blind students by integrating significant research alongside interactive programs. The audience includes students and those responsible for delivering STEM content and educational services to blind students. For students, the program will demonstrate their ability to interface with science center activities. Students will also gain mentoring experience through activities paired with younger blind students. Parents and teachers of blind students, as well as science center personnel, will gain understanding in the experiences of the blind in STEM, and steps to facilitate their complete involvement. Older students will pursue design inquiries into STEM at a more advanced level, processes that would be explored in post-secondary pursuits. By engaging these groups, the NCBYS will build infrastructure in the informal and formal arenas. Society benefits from the inclusion of new scientific minds, resulting in a diverse workforce. The possibility for advanced study and eventual employment for blind students also reduces the possibility that they would be dependent upon society for daily care in the future. The results of the proposed project will be disseminated and published broadly through Web sites; e-mail lists; social media; student-developed e-portfolios of the design program; an audio-described video; and presentations at workshops for STEM educators, teachers of blind students, blind consumer groups, researchers in disability education, and museum personnel.
This article briefly outlines the unique evaluation strategy developed by staff at the Science Museum in London as part of the £50 million Wellcome Wing expansion project. The project aimed to produce "visit-centered" exhibitions that illustrate the impact of contemporary science and technology on ordinary people's lives.
This paper reports a formative evaluation of an interactive exhibit in the Museum of Science, Boston, that encouraged visitors to create a model using everyday materials. The materials provided for visitors to create their models changed during the period of the evaluation, and visitors were observed and interviewed as they engaged with the various prototypes. Evaluation results show that the type of modeling material presented influenced the visitors' model making process and individual learning and behaviors as well as the interactions visitors had with each other.