The Adler Planetarium will expand access to STEM programs for African American and Latinx Chicago teens through a progressive series of entry-point, introductory, intermediate, and advanced level programs. Students in grades 7–12 will be invited to join teams of scientists, engineers, and educators to undertake authentic scientific research and solve real engineering challenges. In collaboration with schools and community-based organizations, Adler will develop and implement new participant recruitment and retention strategies to reach teens in specific neighborhoods. The initiative will help address the underrepresentation of Latinx and African Americans in engineering.
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 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.
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.
Future City, operating since 1992, is “a national, project-based learning experience where students in sixth, seventh, and eighth grade imagine, design, and build cities of the future. Students work as a team with an educator and engineer mentor to plan cities using SimCityTM software, research and write solutions to an engineering problem, build tabletop scale models with recycled materials, and present their ideas before judges at regional competitions in January. Regional winners represent their region at the National Finals in Washington, DC in February.
Future City’s cross-curricular
To build understanding of the essential needs involved in human exploration on Mars, the museum will create the Build a Mars Habitat – Survive and Thrive exhibit which allows museum visitors, especially school field trips and families with children in grades 4-8, to design and construct their own imaginary habitat for successful living on Mars using interchangeable building pieces. This would be designed to appeal particularly to girls, be accessible to audiences using a universal design approach, and be understood by Spanish-language visitors. Partnerships include the National Informal STEM Education Network (NISENet), NASA Ames Research Center, and NASA Marshall Space Flight Center. The project team will also develop professional development materials for both facilitated and unfacilitated experiences to accompany the exhibit. This immersive experience augments the existing “Sun, Earth, Universe” exhibit that was recently distributed to 52 science and children’s museums across the U.S. by NISENet, collectively reporting attendance of over 10 million visitors per year. The exhibition serves as a platform for scientists and museum staff and volunteers to engage visitors with additional facilitated educational programming and hands-on experiences. Anticipated STEM learning outcomes include audience’s increased interest and positive attitudes towards learning about space exploration, increase in informal education professionals’ capacity to engage public audiences in space exploration, and strengthened partnerships among NASA and museums.
Reframing engineering activities to emphasize the needs of others has the potential to strengthen engineering practices like problem scoping, while also providing more inclusive and socially relevant entry points into engineering problems. In a three-year design-based research project, we developed novel strategies for adding narratives to engineering activities to deepen girls’ engagement in engineering practices by evoking empathy for the users of their designs. In this article, we describe a set of hands-on engineering activities developed through iterative development and testing with 190
As professionals, we often assume that the engaging experiences visitors have in our exhibits and programs will lead to long-term learning. But how do we know this is happening, and, moreover, how do we design exhibits, programs and interactions to maximize visitors’ ability to learn from their experiences? At Chicago Children’s Museum a long- standing research collaboration with Northwestern University and Loyola, Chicago University has allowed us to examine how families’ conversational reflections during and after their in-museum experiences impact children’s ability to process and recall
This paper examines the differences and challenges encountered when trying to create informal blended (virtual and hands-on) engineering design STEM activities. It contrasts the creation of STEM activities for formal and informal learning environments, stressing that the differences extend far beyond the length of the activity or depth of any learning goals. The discussion begins with an examination of differences between the two learning environments that need to be taken into consideration. These differences include the physical environments, organizational structures, and the goals or
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.