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.
DiscoverE hired Concord Evaluation Group (CEG) to conduct an independent evaluation of the Future City program. Future City has been operating since 1992. According to DiscoverE, the Future City program is “a national, project-based learning experience where students in 6th, 7th, and 8th 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
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
Black Girls Create (BGC) is a program that uses maker pedagogy, social history (i.e., Black women’s contributions in STEM), culturally responsive pedagogy, and mentoring to engage Black girls in STEM. For the project, culturally responsive making is operationally defined as the use of cultural knowledge and maker technologies to create, design, and produce artifacts that are related to a particular concept, theme, or person. The project will conduct a feasibility research study that investigates how engagement in BGC affects participants' STEM interest, STEM confidence, and racial and gender identities. In the project, participants will discover how Black women have made an impact in STEM fields and will learn how to digitally create cultural artifacts/wearable art related to their discoveries. Approximately 120 middle school girls in grades 6-8 (8 groups of 15 participants each) from underserved neighborhoods will be recruited for participation in this two-year study. Each group will meet for 3 hours per week over an 8-week period. Instructional materials from this research will be made freely available online so that they can be adapted and used at other formal and informal educational institutions that seek to garner interest and access to STEM learning for Black girls and women.
A pre- and post-test, quasi-experimental design will be used to research the program’s influence on participants’ self-efficacy, racial identity, and gender identity. Lagged regression models that control for students’ age, race/ethnicity, and pre-survey scores will be used to examine growth in each of the four outcomes. Once all of the participants in the groups have completed BGC, data from all groups will be combined to increase power and thereby detect statistically meaningful differences in pre- and post-survey scores. In addition, variables representing attendance and program engagement will be entered into the model to examine whether students who are highly engaged in BGC programming exhibit more growth in the four outcomes. Qualitative data will be derived from students' journal entries as well as focus group interviews. Weekly journals will be used to gather data about the context and experiences of participants as they unfold throughout the program. Semi-structured focus groups will center around the usefulness of skills and knowledge gained from the program activities, significant experiences with peers and program staff, the opportunity to learn about Black women STEM progenitors, and learning how to make digitally fabricated artifacts. NVIVO, a computer software program, will be used as a tool to support the analysis of the rich, text-based information resulting from the journals and focus group narratives.
This feasibilty research project is funded by the Advancing Informal STEM Learning (AISL) program, which seeks to (a) advance new approaches to and evidence-based understanding of the design and development of STEM learning in informal environments; (b) provide multiple pathways for broadening access to and engagement in STEM learning experiences; (c) advance innovative research on and assessment of STEM learning in informal environments; and (d) engage the public of all ages in learning STEM in informal environments.
Engaging with Tinkering is a highly stimulating and complex experience and invites rich reflections from museum practitioners and teachers. "Tinkering as an inclusive approach for building STEM identity and supporting students facing disadvantage or with low science capital” presents the reflective practice process and tools designed by the "Tinkering EU: Building Science Capital for All" project aiming to understand in more depth the potential impact of using a Tinkering approach with students facing disadvantage. Using tools specifically designed to help teachers observe their students
The Vertically Integrated Science Learning Opportunity (VISLO) program builds upon an existing three-way partnership between (i) faculty, graduate students, and undergraduate students form the University Nebraska-Lincoln (UNL), (ii) the 21st Century Community Learning Centers (CLC) in Lincoln, NE, and (iii) The University of Nebraska State Museum.
VISLO uniquely incorporates vertically-integrated peer instruction across educational levels, including: graduate, undergraduate, middle school, and elementary school. Throughout the program, participants of all identified educational levels had
In this article we explore how activity design and learning contexts can influence youth failure mindsets through a case study of five youth who described failure as sometimes a good thing and sometimes a bad thing (a perspective we characterize as Failure as Mosaic, described in the article). These youth and their descriptions of failure-positive and failure-negative experiences offer a unique opportunity to identify how experiences can be designed to support learning and persistence. In order to understand differing views of failure among youth, we researched the following questions:
Tinkering creates a bridging point between a learner’s personal interests and experiences and a broad range of possible learning outcomes. It offers valuable opportunities to engage all students in STEM and fosters a more inclusive STEM education. In this way, it is very much aligned with a Science Capital Teaching Approach: fundamentally, it is a highly personalised pedagogy, which allows the learner to follow their own interests and set their own goals.
This resource has been designed to help teachers integrate the Tinkering approach and the Science Capital framework in their practice
This Conference Paper was presented at the International Soceity for the Learning Sciences Confernece in June 2018. We summarize interviews with youth ages 9-15 about their failure mindsets, and if those midsets cross boundaries between learning environments.
Previous research on youth’s perceptions and reactions to failure established a view of failure as a negative, debilitating experience for youth, yet STEM and in particular making programs increasingly promote a pedagogy of failures as productive learning experiences. Looking to unpack perceptions of failure across contexts and