The University of Montana spectrUM Discovery Area will implement “Making Across Montana” —a project to engage K–12 students and teachers in rural and tribal communities with making and tinkering. In collaboration with K–12 education partners in the rural Bitterroot Valley and on the Flathead Indian Reservation, the museum will develop a mobile making and tinkering exhibition and education program. The exhibition will be able to travel to K–12 schools statewide. The project team will develop a K–12 teacher professional development workshop, along with accompanying curriculum resources and supplies. The traveling program and related materials will build schools’ capacity to incorporate making and tinkering—and informal STEM experiences more broadly—into their teaching.
This project is expanding an effective mobile making program to achieve sustainable, widespread impact among underserved youth. Making is a design-based, participant-driven endeavor that is based on a learning by doing pedagogy. For nearly a decade, California State University San Marcos has operated out-of-school making programs for bringing both equipment and university student facilitators to the sites in under-served communities. In collaboration with four other CSU campuses, this project will expand along four dimensions: (a) adding community sites in addition to school sites (b) adding rural contexts in addition to urban/suburban, (c) adding hybrid and online options in addition to in-person), and (d) including future teachers as facilitators in addition to STEM undergraduates. The program uses design thinking as a framework to engage participants in addressing real-world problems that are personally and socially meaningful. Participants will use low- and high-tech tools, such as circuity, coding, and robotics to engage in activities that respond to design challenges. A diverse group of university students will lead weekly, 90-minute activities and serve as near-peer mentors, providing a connection to the university for the youth participants, many of whom will be first-generation college students. The project will significantly expand the Mobile Making program from 12 sites in North San Diego County to 48 sites across California, with nearly 2,000 university facilitators providing 12 hours of programming each year to over 10,000 underserved youth (grades 4th through 8th) during the five-year timeline.
The project research will examine whether the additional sites and program variations result in positive youth and university student outcomes. For youth in grades 4 through 8, the project will evaluate impacts including sustained interest in making and STEM, increased self-efficacy in making and STEM, and a greater sense that making and STEM are relevant to their lives. For university student facilitators, the project will investigate impacts including broadened technical skills, increased leadership and 21st century skills, and increased lifelong interest in STEM outreach/informal science education. Multiple sources of data will be used to research the expanded Mobile Making program's impact on youth and undergraduate participants, compare implementation sites, and understand the program's efficacy when across different communities with diverse learner populations. A mixed methods approach that leverages extant data (attendance numbers, student artifacts), surveys, focus groups, making session feedback forms, observations, and field notes will together be used to assess youth and university student participant outcomes. The project will disaggregate data based on gender, race/ethnicity, grade level, and site to understand the Mobile Making program's impact on youth participants at multiple levels across contexts. The project will further compare findings from different types of implementation sites (e.g., school vs. library), learner groups, (e.g., middle vs. upper elementary students), and facilitator groups (e.g., STEM majors vs. future teachers). This will enable the project to conduct cross-case comparisons between CSU campuses. Project research will also compare findings from urban and rural school sites as well as based on the modality of teaching and learning (e.g., in-person vs. online). The mobile making program activities, project research, and a toolkit for implementing a Mobile maker program will be widely disseminated to researchers, educators, and out-of-school programs.
The Lewis H. Latimer House Museum will develop a more cohesive education program that reflects both the museum's resources and the needs of local schools. The museum's deputy director and Tinkering Lab educator will work together to design a curriculum that meets current New York State and city standards, enabling the museum to more effectively serve schools in the community with object-based learning experiences. Packets of educational materials will be developed and made available for school teachers to download and use in their classrooms prior to and following visits to the museum. Target schools will be actively involved in the process of testing and utilizing the products. Project results will be shared with internal and external stakeholders to sustain long-term improvement and enhance institutional capacity.
The Hands On Children's Museum will build on two of its most distinctive features-an Outdoor Discovery Center and a Young Makers program-to create a Nature Makers program. The interdisciplinary project will link nature-based learning with maker activities that use natural materials. Partnerships with Native American tribes, scientists, maker groups, and others will enrich the staff-led offerings. Nature Makers addresses two of the most significant needs in early learning-inspiring early STEM education and connecting children with the outdoors. Nature Makers will increase children's exposure to outdoor tinkering to build the foundation for STEM success in school; educate parents, caregivers, and teachers about the important role outdoor exploration plays in STEM achievement; and stimulate children's curiosity about the natural world and increase the time they spend outside. Evaluation findings will be shared internally to inform continuous improvement of program offerings, and externally to serve as a model for outdoor making activities.
Described by Wohlwend, Peppler, Keune and Thompson (2017) as “a range of activities that blend design and technology, including textile crafts, robotics, electronics, digital fabrication, mechanical repair or creation, tinkering with everyday appliances, digital storytelling, arts and crafts—in short, fabricating with new technologies to create almost anything” (p. 445), making can open new possibilities for applied, interdisciplinary learning in science, technology, engineering and mathematics (Martin, 2015), in ways that decenter and democratize access to ideas, and promote the construction
DATE:
TEAM MEMBERS:
Jill CastekMichelle Schira HagermanRebecca Woodland
"Making and Tinkering" links science, technology, engineering and mathematics learning (STEM) to the do-it-yourself "maker" movement, where people of all ages "create and share things in both the digital and physical world" (Resnick & Rosenbaum, 2013). This paper examines designing what Resnick and Rosenbaum (2013) call "contexts for tinkerability" within the social design experiment of El Pueblo Mágico (EPM) -- a design approach organized around a cultural historical view of learning and development. We argue that this theoretical perspective reorganizes normative approaches to STEM education
DATE:
TEAM MEMBERS:
Lisa SchwartzDaniela DigiacomoKris Gutierrez
A makerspace is a place where participants explore their own interests and learn by creating, tinkering, and inventing artifacts through the use of a rich variety of tools and materials. This project will develop and research a flexible model for makerspaces that can be adapted to local settings to support informal STEM learning for hospitalized, chronically ill patients in pediatric environments who are predominantly youth of color from low-income backgrounds. These youth are subject to health disparities and healthcare inequities. Their frequent absence from school and other activities disrupt friendship formations, reduce their opportunities for social support, reduce their access to environments where they can feel a sense of self-agency through learning and creative activities. Through patient centered co-design, this project will build adaptable STEM makerspace environments conducive to STEM-rich learning, the exercise of self-agency, and development of STEM identity. Project design will focus on the sensitive nature of working with vulnerable populations (i.e., immunocompromised patients). The project will develop and disseminate several resources: (1) a flexible makerspace model that can be adapted to work in different pediatric settings; (2) research methods for conducting research in highly sensitive environments with and alongside young patients; and (3) professional development resources and a playbook including guidebook and facilitators guide that will articulate principles and processes for designing, implementing and sustaining makerspaces in pediatric settings. These resources will be widely disseminated through maker and other informal STEM networks.
The project will pursue two innovations. First, the project will develop the physical design of adaptable informal STEM makerspaces in pediatric settings. Second, the project will develop innovative patient-centered methodologies for studying approaches to physical design and the effects of makerspace installations for informal STEM-learning, self-agency, and STEM identity development. Using a design-based research approach, the project will investigate: (1) the extent to which physical makerspace designs support access to material, relational, and ideational resources for STEM-learning and well-being; (2) the extent to which makerspace installations, researchers, and medical care staff support patients in accessing and generating tools and other resources for personal learning and a sense of agency; and (3) the extent to which makerspace design with a focus on affording material, relational, and ideational resources provide rich opportunities for young patients to explore their own interests and cultivate STEM identities. One of the project's innovations, beyond development of adaptable makerspace model involves developing an innovative patient-centered methodology for conducting educational research toward broadening participation in STEM in highly sensitive medical care environments. The project will employ a mixed-methods research design and collect a variety of data to address these areas of research including documentation of makerspace design plans and renderings, observational data gathered through fieldnotes, video and audio recordings, informal interviews with patients, their families, and child-care staff, and patient generated artifacts. Articles for researchers and practitioners will be submitted for publication to appropriate professional journals and peer-reviewed publications.
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.
This Innovations in Development 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.
This project responds to calls to increase children's exposure and engagement in STEM at an early age. With the rise of the maker-movement, the informal and formal education sectors have witnessed a dramatic expansion of maker and tinkering spaces, programs, and curricula. This has happened in part because of the potential benefits of tinkering experiences to promote access and equity in engineering education. To realize these benefits, it is necessary to continue to make and iterate design and facilitation approaches that can deepen early engagement in disciplinary practices of engineering and other STEM-relevant skills. This project will investigate how stories can be integrated into informal STEM learning experiences for young children and their families. Stories can be especially effective because they bridge the knowledge and experiences young children and their caregivers bring to tinkering as well as the conversations and hands-on activities that can extend that knowledge. In addition, a unique contribution of the project is to test the hypothesis that stories can also facilitate spatial reasoning, by encouraging children to think about the spatial properties of their emerging structures.
This project uses design-based research methods to advance knowledge and the evidence base for practices that engender story-based tinkering. Using conjecture mapping, the team will specify their initial ideas and how it will be evident that design/practices impact caregivers-child behaviors and learning outcomes. The team will consider the demographic characteristics, linguistic practices, and funds of knowledge of the participants to understand the design practices (resources, activities) being implemented and how they potentially facilitate learning. The outcome of each study/DBR cycle serves as inputs for questions and hypotheses in the next. A culturally diverse group of 300+ children ages 5 to 8 years old and their parents at Chicago Children's Museum's Tinkering Lab will participate in the study to examine the following key questions: (1) What design and facilitation approaches engage young children and their caregivers in creating their own engineering-rich tinkering stories? (2) How can museum exhibit design (e.g., models, interactive displays) and tinkering stories together engender spatial thinking, to further enrich early STEM learning opportunities? and (3) Do the tinkering stories children and their families tell support lasting STEM learning? As part of the overall iterative, design-based approach, the team will also field test the story-based tinkering approaches identified in the first cycles of DBR to be most promising.
This project will result in activities, exhibit components, and training resources that invite visitors' stories into open-ended problem-solving activities. It will advance understanding of mechanisms for encouraging engineering learning and spatial thinking through direct experience interacting with objects, and playful, scaffolded (guided) problem-solving activities.
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 video captures the energy and potetial of the Designing our Tomorrow project. It is intended to complement presentations and posters about Designing our Tomorrow.
The Designing Our Tomorrow project aims to develop a framework for creating exhibit-based engineering design challenges and expand an existing model of facilitation for use in engineering exhibits. Designing our Tomorrow seeks to broaden participation in engineering and build capacity within the informal science education (ISE) field while raising public awareness of the importance of sustainable engineering design practices
This Innovations in Development project is funded by the Advancing Informal STEM Learning (AISL) program, which seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. This includes providing multiple pathways for broadening access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants.
The Designing Our Tomorrow project will develop a framework for creating exhibit-based engineering design challenges and expand an existing model of facilitation for use in engineering exhibits. The project seeks to broaden participation in engineering and build capacity within the informal science education (ISE) field while raising public awareness of the importance of sustainable engineering design practices. The project focuses on girls aged 9-14 and their families and is co-developed with culturally responsive strategies to ensure the inclusion and influence of families from Latino communities. The project will conduct research resulting in theory-based measures of engineering proficiencies within an exhibit context and an exhibit facilitation model for the topic area of engineering. Based on the research, the project will develop an engineering design challenge framework for developing design challenges within an exhibit context. As the context for research, the project will develop a bilingual English/Spanish 2,000-square foot traveling exhibition designed to engage youth and families in engineering design challenges that advance their engineering proficiencies from beginner to more informed, supported by professional development modules and a host-site training workshop introducing strategies for facilitating family engineering experiences within a traveling exhibition. The project is a collaboration of Oregon Museum of Science and Industry with the Biomimicry Institute, Adelante Mujeres, and the Fleet Science Center.
Designing Our Tomorrow builds on a theory-based engineering teaching framework and several previous NSF-funded informal education projects to engage families in compelling design challenges presented through the lens of sustainable design exemplified by biomimicry. Through culturally-responsive co-development and research strategies to include members of Latino communities and provide challenges that highlight the altruistic, creative, personally relevant, and collaborative aspects of engineering, the Designing Our Tomorrow exhibition showcases engineering as an appealing career option for women and helps families support each other's engineering proficiencies. To better understand and promote engineering learning in an ISE setting, the project will conduct two research studies to inform and iteratively develop effective strategies. In the first study, measurement development will build on prior research and practice to design credible and reliable measures of engineering proficiency, awareness, and collaboration, as well as protocols for use in exhibit development and the study of facilitation at engineering exhibits, and future research. The second study will explore the effects of facilitation on the experience outcomes.
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.
Out-of-school settings promise to broaden participation in science to groups that are often left out of school-based opportunities. Increasing such involvement is premised on the notion that science is intricately tied to “the social, material, and personal well-being” of individuals, groups, and nations—indicators and aspirations that are deeply linked with understandings of equity, justice, and democracy. In this essay, the authors argue that dehistoricized and depoliticized meanings of equity, and the accompanying assumptions and goals of equity-oriented research and practice, threaten to
Ideas from social justice can help us understand how equity issues are woven through out-of-school science learning practices. In this paper, I outline how social justice theories, in combination with the concepts of infrastructure access, literacies and community acceptance, can be used to think about equity in out-of-school science learning. I apply these ideas to out-of-school science learning via television, science clubs and maker spaces, looking at research as well as illustrative examples to see how equity challenges are being addressed in practice. I argue that out-of-school science