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1. (Designing for) learning computational STEM and arts integration in culturally sustaining learning ecologies

   https://doi.org/10.1108/ILS-01-2020-0018  

   Champion, Dionne N. ; Tucker-Raymond, Eli ; Millner, Amon ; Gravel, Brian ; Wright, Christopher G. ; Likely, Rasheda ; Allen-Handy, Ayana ; Dandridge, Tikyna M. ( November 2020 , Information and Learning Sciences)

   Purpose The purpose of this paper is to explore the designed cultural ecology of a hip-hop and computational science, technology, engineering, and mathematics (STEM) camp and the ways in which that ecology contributed to culturally sustaining learning experiences for middle school youth. In using the principles of hip-hop as a CSP for design, the authors question how and what practices were supported or emerged and how they became resources for youth engagement in the space. Design/methodology/approach The overall methodology was design research. Through interpretive analysis, it uses an example of four Black girls participating in the camp as they build a computer-controlled DJ battle station. Findings Through a close examination of youth interactions in the designed environment – looking at their communication, spatial arrangements, choices and uses of materials and tools during collaborative project work – the authors show how a learning ecology, designed based on hip-hop and computational practices and shaped by the history and practices of the dance center where the program was held, provided access to ideational, relational, spatial and material resources that became relevant to learning through computational making. The authors also show how youth engagement in the hip-hop computational making learning ecology allowed practices tomore »emerge that led to expansive learning experiences that redefine what it means to engage in computing. Research limitations/implications Implications include how such ecologies might arrange relations of ideas, tools, materials, space and people to support learning and positive identity development. Originality/value Supporting culturally sustaining computational STEM pedagogies, the article argues two original points in informal youth learning 1) an expanded definition of computing based on making grammars and the cultural practices of hip-hop, and 2) attention to cultural ecologies in designing and understanding computational STEM learning environments.« less
2. Partnering to Develop a Coordinated Engineering Education Program Across Schools, Museum Field Trips, and Afterschool Programs

   Harlow, D. ( January 2020 , Connected science learning)

   Engineering Explorations are curriculum modules that engage children across contexts in learning about science and engineering. We used them to leverage multiple education sectors (K–12 schools, museums, higher education, and afterschool programs) across a community to provide engineering learning experiences for youth, while increasing local teachers’ capacity to deliver high-quality engineering learning opportunities that align with school standards. Focusing on multiple partners that serve youth in the same community provides opportunities for long-term collaborations and programs developed in response to local needs. In a significant shift from earlier sets of standards, the Next Generation Science Standards include engineering design, with the goal of providing students with a foundation “to better engage in and aspire to solve the major societal and environmental challenges they will face in decades ahead” (NGSS Lead States 2013, Appendix I). Including engineering in K–12 standards is a positive step forward in introducing students to engineering; however, K–12 teachers are not prepared to facilitate high-quality engineering activities. Research has consistently shown that elementary teachers are not confident in teaching science, especially physical science, and generally have little knowledge of engineering (Trygstad 2013). K–12 teachers, therefore, will need support. Our goal was to create a program that tookmore »advantage of the varied resources across a STEM (science, technology, engineering, and math) education ecosystem to support engineering instruction for youth across multiple contexts, while building the capacity of educators and meeting the needs of each organization. Specifically, we developed mutually reinforcing classroom and field trip activities to improve student learning and a curriculum to improve teacher learning. This challenging task required expertise in school-based standards, engineering education, informal education, teacher professional development, and classroom and museum contexts.« less
3. Applying a Transformative Justice Approach to Encourage the Participation of Black and Latina Girls in Computing

   https://doi.org/10.1145/3451345  

   Erete, Sheena ; Thomas, Karla ; Nacu, Denise ; Dickinson, Jessa ; Thompson, Naomi ; Pinkard, Nichole ( December 2021 , ACM Transactions on Computing Education)

   Global protests and civil unrest in 2020 has renewed the world’s interest in addressing injustice due to structural racism and oppression toward Black and Latinx people in all aspects of society, including computing. In this article, we argue that to address and repair the harm created by institutions, policies, and practices that have systematically excluded Black and Latina girls from computer science, an intersectional, transformative justice approach must be taken. Leveraging testimonial authority, we share our past 8 years of experience designing, implementing, and studying Digital Youth Divas, a programmatic and systemic approach to encouraging middle school Black and Latina girls to participate in STEM. Specifically, we propose three principles to counter structural racism and oppression embedded in society and computing education: computing education must (1) address local histories of injustice by engaging community members; (2) counter negative stereotypes perpetuated in computer science by creating inclusive safe spaces and counter-narratives; and (3) build sustainable, computational capacity in communities. To illustrate each principle, we provide specific examples of the harm created by racist policies and systems and their effect on a specific community. We then describe our attempt to create counter structures and the subsequent outcomes for the girls, their families,more »and the community. This work contributes a framework for STEM and computing educators to integrate transformative justice as a method of repairing the harm that both society and the field of computing has and continues to cause Black and Latinx communities. We charge policy makers, educators, researchers, and community leaders to examine histories of oppression in their communities and to adopt holistic, transformative approaches that counter structural oppression at the individual and system level.« less
4. How youth-staff relationships and program activities promote Latinx adolescent outcomes in a university-community afterschool math enrichment activity

   https://doi.org/10.1080/10888691.2021.1945454  

   Soto-Lara, Stephanie ; Yu, Mark Vincent ; Pantano, Alessandra ; Simpkins, Sandra D. ( July 2021 , Applied Developmental Science)

   outh-staff relationships and program activities are important elements in designing high- quality afterschool activities that promote a broad range of outcomes. Using a qualitative approach, Latinx adolescents were interviewed (n 1⁄4 28, 50% girls) about their experiences in a university-based afterschool math enrichment activity. Findings under the first goal of the study suggest that Latinx adolescents perceived changes in their math-specific outcomes (e.g., problem-solving skills), future science, technology, engineering, and mathematics (STEM) pathways (e.g., envisioning a future career), and social-emotional skills (e.g., relation- ship skills) as a result of participating in the activity. Under the second goal of the study, findings identified the specific practices that adolescents thought promoted those out- comes, including incorporating advanced math concepts and engaging in collaborative learning, engaging in campus tours and informal conversations, and using culturally respon- sive practices. The findings from this study can be leveraged by scholars and educators to design, further strengthen, and evaluate high-quality afterschool activities.
5. Engagement in Practice: Lessons Learned Partnering with Science Educators and Local Engineers in Rural Schools

   Lesko, H. L. ; Grohs, J. R. ; Matusovich, H. M. ; Kirk, G. R. ; Carrico, C. ; van Montfrans, V. ; Gillen, A. L. ; Paradise, T. ; Blackowski, S. A. ; Baum, L. M. ( June 2018 , ASEE Annual Conference proceedings)

   Our NSF-funded ITEST project focuses on the collaborative design, implementation, and study of recurrent hands-on engineering activities with middle school youth in three rural communities in or near Appalachia. To achieve this aim, our team of faculty and graduate students partner with school educators and industry experts embedded in students’ local communities to collectively develop curriculum to aim at teacher-identified science standard and facilitate regular in-class interventions throughout the academic year. Leveraging local expertise is especially critical in this project because family pressures, cultural milieu, and preference for local, stable jobs play considerable roles in how Appalachian youth choose possible careers. Our partner communities have voluntarily opted to participate with us in a shared implementation-research program and as our project unfolds we are responsive to community-identified needs and preferences while maintaining the research program’s integrity. Our primary focus has been working to incorporate hands-on activities into science classrooms aimed at state science standards in recognition of the demands placed on teachers to align classroom time with state standards and associated standardized achievement tests. Our focus on serving diverse communities while being attentive to relevant research such as the preference for local, stable jobs attention to cultural relevance led us tomore »reach out to advanced manufacturing facilities based in the target communities in order to enhance the connection students and teachers feel to local engineers. Each manufacturer has committed to designating several employees (engineers) to co-facilitate interventions six times each academic year. Launching our project has involved coordination across stakeholder groups to understand distinct values, goals, strengths and needs. In the first academic year, we are working with 9 different 6th grade science teachers across 7 schools in 3 counties. Co-facilitating in the classroom are representatives from our project team, graduate student volunteers from across the college of engineering, and volunteering engineers from our three industry partners. Developing this multi-stakeholder partnership has involved discussions and approvals across both school systems (e.g., superintendents, STEM coordinators, teachers) and our industry partners (e.g., managers, HR staff, volunteering engineers). The aim of this engagement-in-practice paper is to explore our lessons learned in navigating the day-to-day challenges of (1) developing and facilitating curriculum at the intersection of science standards, hands-on activities, cultural relevancy, and engineering thinking, (2) collaborating with volunteers from our industry partners and within our own college of engineering in order to deliver content in every science class of our 9 6th grade teachers one full school day/month, and (3) adapting to emergent needs that arise due to school and division differences (e.g., logistics of scheduling and curriculum pacing), community differences across our three counties (e.g., available resources in schools), and partner constraints.« less