KID Museum will develop and test a framework for working with community organizations to design learning experiences and create a facilitation guide for integrating cultural appreciation with maker-based learning. Building on its established Cultural Days programming, the museum will partner with four organizations that represent the region's largest ethnic populations. Together, they will plan, design, prototype, and refine new programs and experiences for children ages 4 to 14 and their families. The project team will adapt an IMLS-funded STEM-expert co-development model to develop and present cultural programs both at the museum and in the community. The project team will evaluate and refine the programs through visitor surveys. The museum will share the resulting framework and facilitation guide with other informal learning spaces to support the implementation of similar programs.
The Fairchild Tropical Botanic Garden will leverage its partnership with NASA Kennedy Space Center to design, equip, and operate an inclusive and interactive scientific research workspace. The new makerspace will provide visitors of all ages an opportunity to contribute to identifying solutions to food production issues. Preparation of the Growing Beyond Earth Innovation Studio will involve equipping the space with state-of-the-art tools and materials for designing and monitoring growing experiments, installing plant growing equipment, and furnishing the space to maximize experimentation, collaboration, and learning. The garden will invite K-12 students, families and casual visitors to collaborate on plant science experiments, allowing them to address questions relevant to current NASA research on food production aboard spacecraft, and within habitats on the surface of Mars.
The Pacific Science Center will develop new evaluation tools to assess the impact of Tinker Tank, a visitor-directed, hands-on design space in which participants are challenged to use their creativity, problem solving, and experience to understand the processes of design, engineering, and science. The project will allow the museum to determine which tools, adapted from both informal learning settings (such as timing and tracking studies, observations, surveys, and focus groups) and formal settings (such as design journals, digital portfolios, and badging),are most suitable for providing meaningful data about the learning and engagement occurring in its makerspace. By adjusting and refining the evaluation tools and methods, the museum will be able to measure learning in its makerspace, determine the extent to which it is achieving the goals and objectives of its Tinker Tank, and guide planning for expansion of making activities into different areas of its exhibition floor.
In partnership with early childhood service providers and elementary school systems, the Children's Museum of the Lowcountry will expand the reach of its programming to share its hands-on, play-based approach to STEM education with targeted children and educators. The museum will create a Power of Play curriculum with lesson plans that reflect best practices and focus on play-based activities to teach STEM concepts tied to grade level and state standards. The museum will train and support 40 teachers and educators from ten Head Start/First Steps early childhood centers and ten Title I elementary schools, and provide them with free Pop Up Tinker Shop (a museum on wheels) outreach visits. The trainings will build teacher confidence, promote best practices for play-based learning, support a community of practice, and enhance young learners' engagement, fascination, and attitude towards STEM. The Power of Play Curriculum will be published as a bound resource and shared with other children's museums and service providers.
This project continues the work of "Tinkering EU: Contemporary Education for Innovators of Tomorrow" that introduced Tinkering methodology in Europe. It also builds upon the work of "Tinkering EU: Building Science Capital for ALL" that explored Tinkering and Science Capital with a specific focus on teachers and students from disadvantaged communities. "Tinkering EU: Addressing the Adults" focusses on fostering the socio-educational and personal development of adults.
Tinkering, inspired by the USA-based experience of the Exploratorium of San Francisco, is proven to be a powerful tool that contributes to the improvement of key competences and skills, and connects science knowledge and skills with the requirements of the contemporary labour market.
The project aims to foster the socio-educational and personal development of adults, as well as their participation in civic and social life, focusing on the following priorities:
Stronger science engagement
Need for 21st Century skills
Low science capital
Coordinator: NEMO Science Museum - The Netherlands
Partners:
National Museum of Science and Technology Leonardo da Vinci – Italy
University of Cambridge – UK
Science Center Network – Austria
Traces – France
Centrum Nauki Kopernik – Poland
As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program funds innovative research, approaches and resources for use in a variety of settings. There are few empirical studies of sustained youth engagement in STEM-oriented making over time, how youth are supported in working towards more robust STEM related projects, on the outcomes of such making experiences among youth from historically marginalized communities, or on the design features of making experiences which support these goals. The project plans to conduct a set of research studies to develop: a theory-based and data-driven framework for equitably consequential making; a set of related individual-level and program-level cases with exemplars (and the associated challenges) that can be used by researchers and practitioners for guiding the field; and an initial set of guiding principles (with indicators) for identifying equitably consequential making in practice. The project will result in a framework for equitably consequential making with guiding principles for implementation that will contribute to the infrastructure for fostering increased opportunities to learn among all youth, especially those historically underrepresented in STEM.
Through research, the project seeks to build capacity among STEM-oriented maker practitioners, researchers and youth in the maker movement around equitably consequential making to expand the prevailing norms of making towards more transformative outcomes for youth. Project research will be guided by several questions. What do youth learn and do (in-the-moment and over time) in making spaces that work to support equity in making? What maker space design features support (or work against) youth in making in equitably consequential ways? What are the individual and community outcomes youth experience in STEM-making across settings and time scales? What are the most salient indicators of equitably consequential making, how do they take shape, how can these indicators be identified in practice? The project will research these questions using interview studies and critical longitudinal ethnography with embedded youth participatory case study methodologies. The research will be conducted in research-practice partnerships involving Michigan State University, the University of North Carolina at Greensboro and 4 local, STEM- and youth-oriented making spaces in Lansing and Greensboro that serve historically underrepresented groups in STEM, with a specific focus on youth from lower-income and African American backgrounds.
Biology has become a powerful and revolutionary technology, uniquely poised to transform and propel innovation in the near future. The skills, tools, and implications of using living systems to engineer innovative solutions to human health and global challenges, however, are still largely foreign and inaccessible to the general public. The life sciences need new ways of effectively engaging diverse audiences in these complex and powerful fields. Bio-Tinkering Playground will leverage a longtime partnership between the Stanford University Department of Genetics and The Tech Museum of Innovation to explore and develop one such powerful new approach.
The objective of Bio-Tinkering Playground is to create and test a groundbreaking type of museum space: a DIY community biology lab and bio-makerspace, complete with a unique repertoire of hands-on experiences. We will tackle the challenge of developing both open-ended bio-making activities and more scaffolded ones that, together, start to do for biology, biotech, and living systems what today’s makerspaces have done for engineering.
A combined Design Challenge Learning, making, and tinkering approach was chosen because of its demonstrated effectiveness at fostering confidence, creative capacity, and problem solving skills as well as engaging participants of diverse backgrounds. This educational model can potentially better keep pace with the emerging and quickly evolving landscape of biotech to better prepare young people for STEM careers and build the next generation of biotech and biomedical innovators.
Experience development will be conducted using an iterative design process that incorporates prototyping and formative evaluation to land on a final cohort of novel, highly-vetted Bio-Tinkering Playground experience. In the end, the project will generate a wealth of resources and learnings to share with the broader science education field. Thus, the impacts of our foundational work can extend well beyond the walls of The Tech as we enable other educators and public institutions around the world to replicate our model for engagement with biology.
This three-year research and implementation project empowers middle school LatinX youth to employ their own assets and funds of knowledge to solve community problems through engineering. Only 7% of adults in the STEM job cluster are of Hispanic/Latino origin. There is a continuing need for filling engineering jobs in our current and future economy. This project will significantly broaden participation of LatinX youth in engineering activities at a critical point as they make career decisions. Design Squad Global LatinX expands on a tested model previously funded by NSF and shown to be successful. It will enable LatinX youth to view themselves as designers and engineers and to build from their strengths to expand their skills and participation in science and engineering. The project goals are to: 1) develop an innovative inclusive approach to informal engineering education for LatinX students that can broaden their engineering participation and that of other underrepresented groups, (2) to galvanize collaborations across diverse local, national, and international stakeholders to create a STEM learning ecosystem and (3) to advance knowledge about a STEM pedagogy that bridges personal-cultural identity and experience with engineering knowledge and skills. Project deliverables include a conceptual framework for a strength-based approach to engineering education for LatinX youth, a program model that is asset based, a collection of educational resources including a club guide for how to scaffold culturally responsive engineering challenge activities, an online training course for club leaders, and a mentoring strategy for university engineering students working with middle school youth. Project partners include the global education organization, iEARN, the Society of Women Engineers, and various University engineering programs.
The research study will employ an experimental study design to evaluate the impact on youth participating in the Design Squad LatinX programs. The key research questions are (1) Does participation increase students' positive perceptions of themselves and understanding of engineering and global perspectives? (2) To what extent do changes in understanding engineering vary by community (site) and by student characteristics (age, gender, ethnicity)? (3) Do educators and club leaders increase their positive perceptions of youths' funds of knowledge and their own understanding of engineering? and (4) Do university mentors increase their ability to lead informal engineering/STEM education with middle school youth? A sample from 72 local Design Squad LatinX clubs with an enrollment of 10-15 students will be drawn with half randomly assigned to the participant condition and half to the control condition. Methods used include pre and post surveys, implementation logs for checks on program implementation, site visits to carry out observations, focus groups with students and interviews with adult leaders. Data will be analyzed by estimating hierarchical linear models with observations. In addition, in-situ ethnographically-oriented observations as well as interviews at two sites will be used to develop qualitative case studies.
This project is funded by the National Science Foundation's (NSF's) Advancing Informal STEM Learning (AISL) program, which supports innovative research, approaches, and resources for use in a variety of learning settings.
Informal learning institutions, such as science centers and museums, are well-positioned to broaden participation in engineering pathways by providing children from underrepresented groups with motivational, self-directed engineering design experiences. Though many informal learning institutions offer opportunities for young visitors to engage in engineering activities, little is known about the specific features of these activities that support children's motivation in engineering design processes such as problem scoping, testing, and iteration. This project will address this gap and advance foundational knowledge by identifying features of engineering design activities, as implemented within an informal setting, which support underrepresented children's engineering motivation and persistence in engineering tasks. Researchers at New York Hall of Science (NYSCI) will observe children interacting with families and museum educators as they engage in different engineering design activities in NYSCI's Design Lab, an exhibition space devoted to hands-on exploration of engineering design. They will also survey and interview the children and their caregivers about these experiences. Analyses of these data sources will result in a description of features of design activities foster motivation and task persistence in engineering design. Findings will be disseminated nationally to other informal learning institutions, which in turn can use the knowledge generated from this project to create motivational, research-based, field-tested engineering design experiences for young visitors, especially for children from underrepresented groups. The experiences may encourage children to further pursue engineering pathways, resulting in a diversified engineering workforce with the potential to drive and sustain national innovation and global technological leadership.
This project uses the framework of goal orientation, defined as learners' self-reflection of why and how they engage in tasks, to understand whether, how, and why underrepresented 7-12-year-olds engage in engineering design activities in an informal learning institution. Though previous research has suggested that goal orientation is strongly, positively related to learning and motivation in formal settings such as schools, research in informal settings has not robustly accounted for the role of goal orientation in participants' engagement with learning tasks in these unique learning environments. To better understand how children's goal orientations contribute to their motivation in engineering in informal learning institutions, researchers will answer the following research questions: (1) What are underrepresented children's goals and goal orientations while participating in engineering design activities in an informal setting? (2) What contextual factors--including facilitation strategies, materials, task relevance, and social interactions with family members--may support or discourage the adoption of different goal orientations? (3) How do goal orientations relate to children's learning experience in the engineering design activities and the likelihood that they will test and iterate their solutions? These questions will be answered through a mixed-method research study conducted with approximately 200 families, with children aged 7-12, recruited from underrepresented groups. Semi-structured clinical interviews, conducted with 20% of the children and their caregivers, as well as observations and surveys gathered from all families, will provide information on the children's goal orientation and engagement as they relate to specific engineering design activities. Qualitative content analyses and multilevel structural equation modeling will result in findings that will be disseminated widely to other institutions of informal learning. Ultimately, this project will generate new empirical knowledge regarding the features of engineering design activities in informal learning environments that increase engineering engagement and motivation among underrepresented children, thereby broadening participation in engineering pathways.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
The project will develop and research the ways in which maker education activities can be leveraged to support intergenerational learning in hyper-vulnerable populations, such as families with an incarcerated parent. Maker education is often linked to STEM learning and uses hands-on and collaborative approaches to support activities and projects that foster creativity, interest, and skill development. Research has shown that maker education activities support STEM learning and creativity, the development of STEM identities and dispositions, and create pathways towards STEM careers. The project will develop a series of project activities including bringing Science, Technology, Engineering, and Mathematics (STEM) learning experts to a women's minimum-security facility for lectures on research and a set of workshops exploring maker activities for the incarcerated women and their children. By researching trauma-informed maker practices for families with an incarcerated parent, the project will develop research findings related to and practical resources for supporting these practices in other informal STEM learning contexts.
While evidence shows that maker pedagogy can be effective in supporting STEM learning for diverse populations, little is known about how it might support STEM learning for incarcerated women and their children. The project will investigate: (1) the everyday STEM practices of incarcerated women and their children and how these practices can be supported and extended through maker activities; (2) how incarcerated women and their children are perceived with respect to STEM and the impact these perceptions have on developing STEM identities; and (3) what design principles for developing STEM learning emerge through the project research. Program activities and related research will be designed and researched through the collaboration of incarcerated women, university researchers from the project university partners, the Saint Louis University Prison Program, and the Federal Correctional Institution-Camp (Greenville Women's Minimum Security Facility). The project will use Social Design Experimentation (SDE) as the primary research method, which is used to design and study education interventions on site. SDE is unique in that participants, researchers and other stakeholders collaborate to meet the goals of the project and related research. Project deliverables, which will be widely disseminated to researchers and educators, will include articles in peer-reviewed and educator publications, strategies and design principles for developing maker education opportunities for hyper-vulnerable populations, and practical recommendations for a maker kit to facilitate STEM maker education activities and family interaction.
This project is funded by the National Science Foundation's (NSF's) Advancing Informal STEM Learning (AISL) program, which supports innovative research, approaches, and resources for use in a variety of learning settings.
This Research Advanced by Interdisciplinary Science and Engineering (RAISE) project is supported by the Division of Research on Learning in the Education and Human Resources Directorate and by the Division of Computing and Communication Foundations in the Computer and Information Science and Engineering Directorate. This interdisciplinary project integrates historical insights from geometric design principles used to craft classical stringed instruments during the Renaissance era with modern insights drawn from computer science principles. The project applies abstract mathematical concepts toward the making and designing of furniture, buildings, paintings, and instruments through a specific example: the making and designing of classical stringed instruments. The research can help instrument makers employ customized software to facilitate a comparison of historical designs that draws on both geometrical proofs and evidence from art history. The project's impacts include the potential to shift in fundamental ways not only how makers think about design and the process of making but also how computer scientists use foundational concepts from programming languages to inform the representation of physical objects. Furthermore, this project develops an alternate teaching method to help students understand mathematics in creative ways and offers specific guidance to current luthiers in areas such as designing the physical structure of a stringed instrument to improve acoustical effect.
The project develops a domain-specific functional programming language based on straight-edge and compass constructions and applies it in three complementary directions. The first direction develops software tools (compilers) to inform the construction of classical stringed instruments based on geometric design principles applied during the Renaissance era. The second direction develops an analytical and computational understanding of the art history of these instruments and explores extensions to other maker domains. The third direction uses this domain-specific language to design an educational software tool. The tool uses a calculative and constructive method to teach Euclidean geometry at the pre-college level and complements the traditional algebraic, proof-based teaching method. The representation of instrument forms by high-level programming abstractions also facilitates their manufacture, with particular focus on the arching of the front and back carved plates --- of considerable acoustic significance --- through the use of computer numerically controlled (CNC) methods. The project's novelties include the domain-specific language itself, which is a programmable form of synthetic geometry, largely without numbers; its application within the contemporary process of violin making and in other maker domains; its use as a foundation for a computational art history, providing analytical insights into the evolution of classical stringed instrument design and its related material culture; and as a constructional, computational approach to teaching geometry.
This project is funded by the National Science Foundation's (NSF's) Advancing Informal STEM Learning (AISL) program, which supports innovative research, approaches, and resources for use in a variety of learning settings.
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. The project will develop and research, as a feasibility study, a series of art-inclusive, pop-up Science, Art, Technology, Engineering, and Mathematics (STEAM) makerspaces in a high-poverty, primarily rural county in Oklahoma. A makerspace is a collaborative work space inside a library, school or other community space for making, learning, exploring and sharing that uses high tech to low tech tools. The makerspaces will be temporary workshops that are developed through a community planning process that assesses the needs and interests of citizen stakeholders. Scientists, artists and other experts will work together with the community to design a series of thematic pop-up makerspace sessions. The project builds a collaborative infrastructure and capacity for small and rural communities by bringing together resource providers and experts to identify and design science-oriented challenges. Long-term benefits for participants include sustained focus on new approaches for civic engagement through STEAM-driven making which could foster new role identities pertaining to science and art. The project deliverables include: (1) a theoretically informed model to build a community's capacity to collaborate toward fostering civic engagement through science-oriented pop-up makerspaces, (2) Pop-Up STEAM Studio makerspaces, (3) training for pop-up facilitators, and (4) visual documentation panels and web-based digital stories to communicate progress and process.
Project research will enhance knowledge-building of the process of developing a science-oriented community challenge that embraces STEAM and making. A key contribution of the proposed project will be the generation of insights into how community members establish consensus around the joint goal of designing, documenting, and facilitating integrated art and science making activities to address and communicate the challenge. Research will focus on the roles participants take when engaging in the making process through an identity-based model of motivated action. Analysis of advisory board meeting artifacts and focus group data will allow the researchers to identify processes of negotiation and consensus building at the collective level and in relation to each issue to which the group attends. Emergent themes (such as negotiation, shared learning, idea or project revisions, diverse perspectives coming to consensus, etc.) will be examined across individual and group units of analysis, from all data sources, and through the congruent theoretical lenses of role identity theory and negotiated learning pedagogy. The research outcomes should inform efforts to build infrastructure and capacity of community resources by providing a model for developing collaborative pop-up makerspaces.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
DATE:
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TEAM MEMBERS:
Sheri VasindaJoanna GarnerStephanie HathcockRebecca Brienen