Making as a term has gained attention in the educational field. It signals many different meanings to many different groups, yet is not clearly defined. This project’s researchers refer to making as a term that bears social and cultural impact but with a broader more sociocultural association than definitions that center making in STEM learning. Using the theoretical lenses of critical relationality and embodiment, our research team position curriculum as a set of locally situated activities that are culturally, linguistically, socially, and politically influenced. We argue that curriculum
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TEAM MEMBERS:
Veronica OguilveWen WenEm BowenYousra AbourehabAmanda BermudezElizabeth GaxiolaJill Castek
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
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TEAM MEMBERS:
Jill CastekMichelle Schira HagermanRebecca Woodland
There is a dearth of prominent STEM role models for underrepresented populations. For example, according to a 2017 survey, only 3.1% of physicists in the United States are Black, only 2.1% are Hispanic, and only 0.5% are Native American. The project will help bridge these gaps by developing exhibits that include simulations of historical scientific experiments enacted by little-known scientists of color, virtual reality encounters that immerse participants in the scientists' discovery process, and other content that allows visitors to interact with the exhibits and explore the exhibits' themes. The project will develop transportable, interactive exhibits focusing on light: how we perceive light, sources of light from light bulbs to stars, uses of real and artificial light in human endeavors, and past and current STEM innovators whose work helps us understand, create, and harness light now. The exhibits will be developed in three stages, each exploring a characteristic of light (Color, Energy, or Time). Each theme will be explored via multiple deliveries: short documentary and animated films, virtual reality experiences, interactive "photobooths," and technology-based inquiry activities. The exhibit components will be copied at seven additional sites, which will host the exhibits for their audiences, and the project's digital assets will enable other STEM learning organizations to duplicate the exhibits. The exhibits will be designed to address common gaps in understanding, among adults as well as younger learners, about light. What light really is and does, in scientific terms, is one type of hidden story these exhibits will convey to general audiences. Two other types of science stories the exhibits will tell: how contemporary research related to light, particularly in astrophysics, is unveiling the hidden stories of our universe; and hidden stories of STEM innovators, past and present, women and men, from diverse backgrounds. These stories will provide needed role models for the adolescent learners, helping them learn complex STEM content while showing them how scientific research is conducted and the diverse community of people who can contribute to STEM innovations and discoveries.
The project deliverables will be designed to present complex physics content through coherent, immersive, and embodied learning experiences that have been demonstrated to promote engagement and deeper learning. The project will research whether participants, through interacting with these exhibits, can begin to integrate discrete ideas and make connections with complex scientific content that would be difficult without technology support. For example, students and other novices often lack the expertise necessary to make distinctions between what is needed and what is extra within scientific problems. The proposed study follows a Design-Based Research (DBR) approach characterized by iterative cycles of data collection, analysis, and reflection to inform the design of educational innovations and advance educational theory. Project research includes conceiving, building, and testing iterative phases, which will enable the project to capture the complexity of learning and engagement in informal learning settings. Research participants will complete a range of research activities, including focus group interviews, observation, and pre-post assessment of science content knowledge and dispositions.
By showcasing such role models and informing about related STEM content, this project will widen perspectives of audiences in informal learning settings, particularly adolescents from groups underrepresented in STEM fields. Research findings and methodologies will be shared widely in the informal STEM learning community, building the field's knowledge of effective ways to broaden participation in informal science learning, and thus increase broaden participation in and preparation for the STEM-based workforce.
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.
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TEAM MEMBERS:
Todd BoyetteJill HammJanice AndersonCrystal Harden
AHA! Island is a new project that uses animation, live-action videos, and hands-on activities to support joint engagement of children and caregivers around computational thinking concepts and practices. This research is intended to examine the extent to which the prototyped media and activity sets support the project’s learning goals. Education Development Center (EDC), WGBH’s research partner for the project, conducted a small formative study with 16 English-speaking families (children and their caregivers) to test out these media and activity set prototypes. During the in-person video
The maker movement has evoked interest for its role in breaking down barriers to STEM learning. However, few empirical studies document how youth are supported over time, in STEM-rich making projects or their outcomes. This longitudinal critical ethnographic study traces the development of 41 youth maker projects in two community-centered making programs. Building a conceptual argument for an equity-oriented culture of making, the authors discuss the ways in which making with and in community opened opportunities for youth to project their communities’ rich culture knowledge and wisdom onto
This research paper critically explores the common definitions and perceptions of Making that may potentially disenfranchise traditionally underrepresented groups in engineering. Given the aspects of engineering design that are commonly integrated into Making activities, the Maker movement is increasingly recognized as a potentially transformative pathway for young people to developing early interest and understanding in engineering. However, “what counts” as Making can often be focused heavily on electronic-based and computational forms of Making, such as activities that involve 3D printers
It is a well-documented fact that women and minorities are currently underrepresented in STEM higher education degree programs and careers. As an outreach measure to these populations, we established the Hexacago Health Academy (HHA), an ongoing summer program. Structured as an informal learning environment with a strong youth initiated mentoring component, HHA uses game-based learning as both a means of health education and stimulating interest in careers in medicine among adolescents from underrepresented minority populations. In this article, we describe the 2015 session of the Hexacago
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TEAM MEMBERS:
Megan MacklinPatrick JagodaIan B. JonesMelissa Gilliam
Large gaps in achievement and interest in science and engineering [STEM] persist for youth growing up in poverty, and in particular for African American and Latino youth. Within the informal community, the recently evolving “maker movement” has evoked interest for its potential role in breaking down longstanding barriers to learning and attainment in STEM, with advocates arguing for its “democratizing effects.” What remains unclear is how minoritized newcomers to a makerspace can access and engage in makerspaces in robust and equitably consequential ways.
This paper describes how and why
We present a review of an after-school program that has been running at Queensborough Community College of the City University of New York for the past 5 years. The program is unique among after-school activities for high school students in several ways. First, it deliberately focuses on students who do not excel in science and math courses and students who are unsure about a college career. Second, it targets typically underrepresented minorities in the technology fields, namely blacks, Hispanics, and women. Third, it introduces these students to high-tech career options which do not require
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TEAM MEMBERS:
Amy BieberPaul MarcheseDon Engelberg
This presentation given at the 2013 Materials Research Society (MRS) Spring Meeting examines evidence for the effectiveness of STEM education programs at the National High Magnetic Field Laboratory.
Techbridge has proposed a broad implementation project that will scale up a tested multi-faceted model that increases girls' interest in STEM careers. The objectives of this project are to increase girls' engineering, technology, and science skills and career interests; build STEM capacity and sustainability across communities; enhance STEM and career exploration for underrepresented girls and their families; and advance research on the scale-up, sustainability, and impact of the model with career exploration. The Techbridge approach is grounded in Eccles' expectancy value model, and helps bridge critical junctures as girls transition from elementary to middle school and middle school to high school, immersing participants in a network of peers and supportive adults. Techbridge targets girls in grades 5-12 with a model that includes five components: a previously tested and evaluated curriculum, career exploration, professional development for staff and teachers, family engagement, and dissemination. The inquiry-based curriculum introduces electrical engineering and computer science through engaging, hands-on units on Cars and Engines, Green Design, and Electrical Engineering. The Techbridge model will be enhanced to include a central repository for curriculum and support materials, electronic girl-driven career exploration resources, an online learning community and video tools for staff, and customized family guides. Project deliverables include the dissemination of the enhanced model to three cities, 24 school sites and teachers, 2,000 girls, and over 600 role models. A supplementary research component will study the broad implementation of the Techbridge model by examining the fidelity of implementation and the program's impact on girls' STEM engagement and learning. The research questions are as follows: (1) To what extent and how do new program sites demonstrate adherence to the Techbridge program model? (2) Do new sites experience similar or increased participant responsiveness to Techbridge programming with regard to scientific learning outcomes, career awareness, attitude and interest in engineering? (3)How are changes experienced by girls sustained over time, if at all? (4) To what extent and how do new sites balance instilling the Techbridge essentials, those critical components Techbridge identifies as essential for success, with the need for local adaptation and ownership of the program? and (5) Given the potential for customization in local communities, do new sites maintain programmatic quality of delivery experienced at the original site? If so, what are elements essential to success regarding quality delivery? The mixed-methods study will include document analysis, embedded assessments, participant survey scales, and observations. Qualitative data methods include interviews with teachers, role models, staff and focus groups with girls. A project evaluation will also be conducted which investigates project outcomes for participants (girls, teachers, role models, and families) and fidelity of the implementation and enhancements at expansion sites, using a quasi-experimental approach. Career and learning outcomes for girls will be determined using embedded assessments, portfolios, surveys, school data, and previously validated instruments such as the Career Interest Questionnaire and the Modified Attitudes towards Science Inventory. The Managing Complex Change model is used as a framework for the project evaluation for the purpose of examining factors related to the effectiveness of scaling. The dissemination of research and evaluation findings will be achieved through the use of publications, blogs, social media, and conferences. It is anticipated that this project will broaden the participation of Hispanic, African-American, and English language learner girls, build capacity for STEM programming and sustainability at the dissemination sites, and disseminate findings to over 1 million educators, researchers, and community members. Broader impacts include contributing to the field's understanding of how virtual role models and field trips can engage young women, increase corporate advocacy, and engage participants in research and dissemination efforts.