To advance justice, equity, diversity, and inclusion in science, we must first understand and improve the dominant-culture frameworks that impede progress and, second, we must intentionally create more equitable models. The present authors call ourselves the ICBOs and Allies Workgroup (ICBOs stands for independent community-based organizations), and we represent communities historically excluded from the sciences. Together with institutional allies and advisors, we began our research because we wanted our voices to be heard, and we hoped to bring a different perspective to doing science with
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TEAM MEMBERS:
María Cecilia Alvarez RicaldeJuan Flores ValadezCatherine CrumJohn AnnoniRick BonneyMateo Luna CastelliMarilú López FrettsBrigid LuceyKaren PurcellJ. Marcelo BontaPatricia CampbellMakeda CheatomBerenice RodriguezYao Augustine FoliJosé GonzálezJosé Miguel Hernández HurtadoSister Sharon HoraceKaren KitchenPepe Marcos-IgaTanya SchuhPhyllis Edwards TurnerBobby WilsonFanny Villarreal
A collaboration of TERC, MIT, The Woods Hole Oceanographic Institution and community-based dance centers in Boston, this exploratory project seeks to address two main issues in informal science learning: 1) broadening participation in science by exploring how to expand science access to African-American and Latino youth and 2) augmenting science learning in informal contexts, specifically learning physics in community-based dance sites. Building on the growing field of "embodied learning," the project is an outgrowth in part of activities over the past decade at TERC and MIT that have investigated approaches to linking science, human movement and dance. Research in embodied learning investigates how the whole body, not just the brain, contributes to learning. Such research is exploring the potential impacts on learning in school settings and, in this case, in out of school environments. This project is comprised of two parts, the first being an exploration of how African-American and Latino high school students experience learning in the context of robust informal arts-based learning environments such as community dance studios. In the second phase, the collaborative team will then identify and pilot an intervention that includes principles for embodied learning of science, specifically in physics. This phase will begin with MIT undergraduate and graduate students developing the course before transitioning to the community dance studios. This 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 goal of this pilot feasibility study is to build resources for science learning environments in which African-American and Latino students can develop identities as people who practice and are engaged in scientific inquiry. Youth will work with choreographers, physicists and educators to embody carefully selected physics topics. The guiding hypothesis is that authentic inquiries into scientific topics and methods through embodied learning approaches can provide rich opportunities for African-American and Latino high school-aged youth to learn key ideas in physics and to strengthen confidence in their ability to become scientists. A design- based research approach will be used, with data being derived from surveys, interviews, observational field notes, video documentation, a case study, and physical artifacts produced by participants. The study will provide the groundwork for producing a set of potential design principles for future projects relating to informal learning contexts, art and science education with African American and Latino youth.
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TEAM MEMBERS:
Folashade Cromwell SolomonTracey WrightLawrence Pratt
In this case study, we highlight the work of the Bay Area STEM Ecosystem, which aims to increase equity and access to STEM learning opportunities in underserved communities. First, we lay out the problems they are trying to solve and give a high level overview of the Bay Area STEM Ecosystem’s approach to addressing them. Then, based on field observations and interviews, we highlight both the successes and some missed opportunities from the first collaborative program of this Ecosystem. Both the successes of The Bay Area STEM Ecosystem--as well as the partners’ willingness to share and examine
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.
The CASE program served communities that are underrepresented in current museum audiences. CASE served both females and males from underrepresented minority groups, primarily African American, Latino, and Asian. The most frequent participants were younger than 20 years-old and African American. CASE succeeded in making informal science learning accessible in participating communities. CASE served a total of 10,971 individuals between September 2004 and December 2008. Across the five years, families in the eight participating sites had a grand total of 358 opportunities to attend science