The Oregon Museum of Science and Industry will inspire diverse youth and families to use 21st century skills by creating hands-on Design Challenges where visitors work together to design and test multidisciplinary sustainable solutions to real-world problems. The museum will work closely with Oregon MESA, an organization that uses human-centered Design Challenges to teach STEM, invention, and 21st Century Skills to middle and high school students historically underrepresented in STEM fields. Project deliverables will include three Design Challenges; a Design Challenge Collaboration Playbook outlining how to develop Design Challenges using human-centered design in collaboration with MESA youth, families, and staff; and A MESA-OMSI Collaboration Sustainability Plan that lays out how to continue the partnership and programs beyond the grant. The impacts on families will be explored during front-end, formative, and summative evaluation activities.
Miami Children's Museum will redesign its Construction Zone Gallery into a STEM-learning space providing children, primarily ages eight and under, with a stimulating and interactive experience. The exhibition will incorporate 13 distinctive exhibition components, allowing full engagement in a variety of STEM-based learning activities. The museum will conduct focus group activities with field interpreters, specialists and educators working in STEM fields to guide and refine content development of the script and exhibition layout, followed by testing of the themes, programming activities, exhibition props and tools, software concepts, and learning outcomes. The project team will develop accompanying programming for children to be presented at the museum and at area public libraries. All components of the exhibition will support Florida's Early Learning Standards, and will meet the evolving educational needs of its youngest learners.
Clark Planetarium will partner with the Salt Lake County Library System to extend STEM education for adolescent audiences throughout the regional community. The planetarium will create STEM classes in up to 18 different county libraries, with up to four library activity sessions each week. With each activity session, the project will engage middle school and high school aged participants in hands-on science, technology, and engineering activities that explore complex concepts and principles through simulations of robotic missions. Each visit will engage learners in STEM-focused activities that emphasize group work such as building robots, collecting and analyzing data, and solving problems. Over the span of three years, the project will reach over 7,700 teens. The Utah Education Policy Center will use observation, program records, and a brief online survey to measure the program's impact on STEM interest and improvement in confidence, attitudes, and behavioral intentions around STEM.
Sciencenter will develop a touring exhibition, Engineer.Design.Build, to spark interest and build confidence in STEM by providing learning opportunities about the broad impact engineers have on the environment and society. The museum will partner with Cornell University's College of Engineering to develop scientific content which will be reviewed by an advisory board of representatives from the academic, business, and informal science education sectors. Partners from informal learning institutions will provide expertise on the educational content to ensure that it is accessible and engaging for the target audience of 5-11 year olds. Through a combination of focus groups, youth/guest feedback during exhibition development, and experts in girls' engagement in STEM on the advisory board, the museum will ensure that the exhibition and programming are designed to appeal to girls, and accessible to all learners. The project will include front-end, formative, and summative evaluation through observations and mediated interviews, collecting data from youth, families, and school groups.
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.
The Bay Area Discovery Museum will address the need for STEM education by delivering engineering outreach programming to schools and libraries throughout the San Francisco Bay Area. The museum's mobile engineering lab, Try It Truck, will introduce the engineering design process to students and teachers in grades K-5 with hands-on activities (both on and off the truck) where they can collaborate, experiment, and design solutions to engineering challenges. The Try It Truck will serve 21,600 children, parents, and educators throughout the Bay Area, with at least 50 percent of all participants coming from underserved communities and Title I schools. The museum will work with an external evaluator to design survey instruments for both formative and summative evaluation, analyze summative evaluation data, and produce a report. Museum staff will share project results with colleagues at national and statewide conferences.
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.
The Children's Museum at La Habra's Lil' Innovators Early Childhood STEM project will increase STEM skill and engagement among early childhood preschool teachers, disadvantaged preschoolers, and their parents. Delivered in partnership with three of La Habra's Head Start and California State Preschool program schools, the project will provide 224 preschoolers and 20 teachers with a year-long program offering increased developmental skills in STEM for underserved, low-income Hispanic students who are primarily English Language Learners. Teacher outcomes will include improved strategies for teaching STEM and increased teaching quality of STEM subjects. Parent outcomes include increased belief in the importance of STEM and increased ability to support their child's STEM learning. The standards-based education project will improve the museum's ability to serve its public by creating a community of practice consisting of a network of administrators, educators, and evaluators who will work together to improve the quality of STEM education for the youngest learners in this academically-challenged community.
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.
The EEE project focused on creating approaches for engineering experts to incorporate objects and oral narratives into family STEM programs. The engineering experts included tinkerers, mechanical, nuclear and costume engineers, with varying levels of experience and backgrounds. These experts work with the research team, Museum and Library, to create a workshop or program where children and their families can create a novel project following engineering concepts.
One way to motivate young people from diverse backgrounds to pursue engineering careers is to enlist them as educators who can help the general public understand how engineers help respond to the challenges of everyday life. The New York Hall of Science, which serves a large and diverse audience, is an ideal setting for testing the promise of this strategy. Youth educators and curators of public programs at the Hall of Science will mentor two groups of high school- and early college-aged youth, who will contribute to the design and facilitation of engineering-focused events and activities for museum visitors. They will work together to develop engineering programming for the public that emphasizes the cultural and interpersonal dimensions of engineering practices. This group of young people will be recruited from the Hall of Science's more than 100 Explainers, a very diverse group of young people who work part-time at the Hall of Science and engage with visitors as they explore the museum. Researchers will track participants' experiences and document their impact on museum visitors' perceptions of engineering. The expectation is that creating and delivering these experiences for visitors will have a positive impact on the youth participants' understanding of the engineering disciplines, and on visitors' perceptions of engineering and its relationship to everyday life.
The project will use observations, interviews, journaling, and the Engineering Professional Skills Assessment to explore youth experience, and visitor exit surveys and interviews to probe visitor perceptions. Both the skills assessment and visitor surveys are NSF-funded instruments. Data coding will be grounded in the engineering habits of mind defined by the National Research Council's Committee on Understanding and Improving K-12 Engineering Education in the United States (2009). The project will capture evidence regarding which habits of mind the Fellows are most frequently engaged with. The effort will also explore how interactions with peers (as colleagues), with experts (as learners, such as with Designers in Residence) and with visitors (as teachers and leaders) may be associated with different combinations of the habits of mind over the course of the project. Visitor data and assessment data will allow the project to begin to make analytic connections between participating young people's increased understanding of culturally-situated engineering challenges, and their impact on the experiences of museum visitors who engage with engineering programming at the Hall of Science.
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.