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1. Changes in Teacher Self-efficacy Through Engagement in an Engineering Professional Development Partnership

   https://doi.org/10.18260/1-2--34272  

   Schilling, Malle ; Paradise, Tawni ; Grohs, Jacob ; Matusovich, Holly ; Carrico, Cheryl ; Lesko, Holly ; Kirk, Gary ( June 2020 , ASEE Annual Conference)

   null (Ed.)

   K-12 teachers serve a critical role in their students’ development of interest in engineering, especially as engineering content is emphasized in curriculum standards. However, teachers may not be comfortable teaching engineering in their classrooms as it can require a different set of skills from which they are trained. Professional development activities focused on engineering content can help teachers feel more comfortable teaching the subject in their classrooms and can increase their knowledge of engineering and thus their engineering teaching self-efficacy. There are many different types of professional development activities teachers might experience, each one with a set of established best practices. VT PEERS (Virginia Tech Partnering with Educators and Engineers in Rural Communities) is a program designed to provide recurrent hands-on engineering activities to middle school students in or near rural Appalachia. The project partners middle school teachers, university affiliates, and local industry partners throughout the state region to develop and implement engineering activities that align with state defined standards of learning (SOLs). Throughout this partnership, teachers co-facilitate engineering activities in their classrooms throughout the year with the other partners, and teachers have the opportunity to participate in a two-day collaborative workshop every year. VT PEERS held a workshop during the summer of 2019, after the second year of the partnership, to discuss the successes and challenges experienced throughout the program. Three focus groups, one for each grade level involved (grades 6-8), were held during the summit for teachers and industry partners to discuss their experiences. None of the teachers involved in the partnership have formal training in engineering. The transcripts of these focus groups were the focus of the exploratory qualitative data analyses to answer the following research question: How do middle-school teachers develop teaching engineering self-efficacy through professional development activities? Deductive coding of the focus group transcripts was completed using the four sources of self-efficacy: mastery experience, vicarious experience, verbal persuasion and physiological states. The analysis revealed that vicarious experiences can be particularly valuable to increasing teachers’ teaching engineering self-efficacy. For example, teachers valued the ability to play the role of a student in an engineering lesson and being able to share ideas about teaching engineering lessons with other teachers. This information can be useful to develop engineering-focused professional development activities for teachers. Additionally, as teachers gather information from their teaching engineering vicarious experiences, they can inform their own teaching practices and practice reflective teaching as they teach lessons. 

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2. Designing a framework for teachers' integration of computational thinking into elementary science

   https://doi.org/10.1002/tea.21888  

   Cabrera, Lautaro ; Ketelhut, Diane Jass ; Mills, Kelly ; Killen, Heather ; Coenraad, Merijke ; Byrne, Virginia L. ; Plane, Jandelyn Dawn ( July 2023 , Journal of Research in Science Teaching)

   As professional science becomes increasingly computational, researchers and educators are advocating for the integration of computational thinking (CT) into science education. Researchers and policymakers have argued that CT learning opportunities should begin in elementary school and span across the K‐12 grades. While researchers and policymakers have specified how students should engage in CT for science learning, the success of CT integration ultimately depends on how elementary teachers implement CT in their science lessons. This new demand for teachers who can integrate CT has created a need for effective conceptual tools that teacher educators and professional development designers can use to develop elementary teachers' understanding and operationalization of CT for their classrooms. However, existing frameworks for CT integration have limitations. Existing frameworks either overlook the elementary grades, conceptualize CT in isolation and not integrated into science, and/or have not been tested in teacher education contexts. After reviewing existing CT integration frameworks and detailing an important gap in the science teacher education literature, we present our framework for the integration of CT into elementary science education, with a special focus on how to use this framework with teachers. Situated within our design‐based research study, we (a) explain the decision‐making process of designing the framework; (b) describe the pedagogical affordances and challenges it provided as we implemented it with a cohort of pre‐ and in‐service teachers; (c) provide suggestions for its use in teacher education contexts; and (d) theorize possible pathways to continue its refinement.

    

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3. Examining the Role of Mentor Teacher Support in a Professional Learning Experience for Preservice Teachers on Integrating Computational Thinking into Elementary Science Education

   Ketelhut, D. J. ; Hestness, E. ; Cabrera, L. ; Jeong, H. ; Plane, J. ; & McGinnis, J. R. ( April 2019 , Society for Information Technology & Teacher Education International Conference)

   Abstract. We investigated preservice teachers’ (PSTs) (N=13) experiences in a science teaching inquiry group professional learning experience on integrating computational thinking (CT) into elementary science. A subgroup of PSTs (n=6) participated alongside their mentor teachers. The others (n=7) participated independently. Our research question was: To what extent, if any, did participating in a professional learning experience on CT along with their mentor teachers appear to enhance PSTs’ learning and practice related to CT integration? We analyzed evaluation feedback, interviews, participant-developed lesson plans, surveys, and attendance data. Findings suggested that participants in both groups reacted positively to the learning experience’s content and approach, and expressed similar perceptions of their CT integration knowledge. PSTs participating with their mentor teachers felt slightly more successful in their CT integration efforts, and perceived CT integration as more feasible in their teaching contexts. However, differences between the groups were minimal. We also noted possible of influence of PSTs’ perceptions of the districts in which they were teaching. Our findings underscore the importance of PSTs’ perceptions of their teaching contexts when bringing a new innovation to the classroom - namely, perceptions of their mentors and curricula as supportive of the innovation. Through this ongoing work, we seek to identify empirically-supported strategies for preparing PSTs to integrate CT into their future classrooms. 

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4. How a Research-Practice Partnership Refined its Strategy for Integrating CS/CT into K-5 Curricula: An Experience Report

   https://doi.org/10.1145/3478431.3499281  

   Adrion, W. Richards ; Bevan, Katie ; Foster, Paul ; Matuszczak, Denise ; Miller, Rachel ; Rita, Laura ; Sullivan, Florence R. ; Veeragoudar, Sneha ; Wohlers, Scott ; Zeitz, Melissa ( March 2022 , SIGCSE ’22)

   Massachusetts defined K-12 Digital Literacy/Computer Science (DLCS) standards in 2016 and developed a 5-12 teacher licensure process, expecting K-4 teachers to be capable of teaching to the standards under their elementary license. An NSF CSforAll planning grant led to the establishment of an NSF 4-year ResearchPractice Partnership (RPP) of district and school administrators, teachers, university researchers, and external evaluators in 2018. The RPP focused on the 33 K-5 serving schools to engage all students in integrated CS/CT teaching and learning and to create a cadre of skilled and confident elementary classroom teachers ready to support their students in learning CS/CT concepts and practices. The pandemic exacerbated barriers and inequities across the district, which serves over 25,000 diverse students (9.7% white/nonHispanic, 83.7% high needs). Having observed a lack of awareness and expertise among many K-5 teachers for implementing CS/CT content and practices and seeing barriers to equitable CS/CT teaching and learning, the RPP designed an iterative, teacher-led, co-design of curriculum supported by equity-focused and embedded professional learning. This experience report describes how we refined our strategies for curriculum development and diffusion, professional learning, and importantly, our commitment to addressing diversity, equity, and inclusion beyond just reaching all students. The RPP broadened its focus on understanding race and equity to empower students to understand how technology affects their identities and to equip them to critically participate in the creation and use of technology 

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5. Embedding Computational Thinking in the Elementary Classroom: An Extended Collaborative Teacher Learning Experience

   Ketelhut, D.J. ; Hestness, E. ; Mills, K. ( July 2019 , Computer-supported collaborative learning)

   Abstract: We used design-based research to investigate an extended professional learning experience to prepare teachers to embed computational thinking in elementary science. Opportunities to interact synchronously in a community of practice - including through in person engagement in embodied challenges, discussion, and resource sharing, appeared to productively support teacher preparedness to embed CT in their science teaching. However, asynchronous collaboration via an online platform was less effective. We describe planned adjustments for future iterations of the program. 

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