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1. Professional Learning Externship as a Strategy to Increase Educator Understanding of Emerging Technological Fields

   https://doi.org/10.5281/zenodo.10929118  

   Labrie, Josh; Schuh-Nuhfer, Natasha; Russell, Christopher; Gruber, Jennifer A (January 2024, Journal of advanced technological education)

   Markets with emerging technologies face a challenge in finding employees with the knowledge base and skills necessary to fulfill their workforce needs. Generating awareness of these career fields is essential to meet workforce needs now and into the future. This paper discusses the extent to which educator awareness of the engineering technology (ET) and data center operations (DCO) programs and careers change as a result of participation in a professional learning (PL) externship program. Secondary educators in the PL program learned specifics of Northern Virginia Community College’s (NOVA) ET programs, toured an ET facility and data center, and developed a plan to disseminate the ET credentialing and career information to their colleagues, students, and parents. In post-participation surveys, educators indicated increased awareness of and interest in ET education programs and career pathways. Additionally, educators indicated an understanding of the industry’s need for ET talent and the skills and technical knowledge students need for ET careers. The data supports an educator externship as a PL mechanism for post-secondary institutions to increase awareness of the educational pathways and careers in emerging technologies. 

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2. Polyphony of (Analytical) Scores, Co‐Design, and Creative Methodologies

   https://doi.org/10.1111/jade.12583  

   Koro, Mirka; Vasquez, Ananí M; Reutlinger, Corey; McLeod, Cole (April 2025, International Journal of Art & Design Education)

   Abstract This experimental paper explores a form of neurodiversity‐affirming qualitative data analysis labelled a polyphony of (analytical) scores and creative methodologies utilised in our research project. Our data examples come from a federally funded research study which co‐designed sensory pedagogies for autistic students interested in computational thinking (CT). Four middle‐school teachers, or teacher fellows (TF), from diverse disciplines were recruited to develop neurodiverse CT mini curriculum and pedagogies for middle‐school students interested in STEM. Teacher fellows worked with the research team to co‐design teaching and learning materials and technology to explore computational thinking. The research team and teacher fellows attended workshops that included creative ensemble activities using digital‐physical musical technologies and CT concepts. Data from these workshops were used to create two polyphonic score compositions as ways to interact with data. A video creation addressed how TFs were impacted during the development and implementation of neurodiverse pedagogies. Quotes and keywords extracted for the video creation reflect how silence and sound collapse and expand in a rhizomatic fashion, indicating how TFs experience messiness, exploration, atypicality and more, which fully represent neurodiversity. The score analysis enabled us to diversify participants' experiences with neurodiverse pedagogies and illustrated the affective dimensions of musical composition as a form of data analysis. 

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3. Designing approximations of practice: The case of teacher noticing

   Bailey, Nina G; McCulloch, Allison W; Dick, Lara K; Lovett, Jennifer N; Yalman_Özen, D; Cayton, C (August 2024, Journal of Educational Research in Mathematics)

   As a core practice, teacher noticing of students' mathematical thinking is foundational to other teaching practices. Yet, this practice is difficult for preservice teachers (PSTs), particularly the component of interpreting students' thinking (e.g., Teuscher et al., 2017). We report on a study of our design of a specific approximation of teacher noticing task with the overarching goal of conceptualizing how to design approximations of practice that support PSTs' learning to notice student thinking in technology-mediated environments with a specific focus on interpreting students' mathematical thinking. Drawing on Grossman et al.'s (2009) Framework for Teaching Practice (i.e., pedagogies of practice), we provided decomposed opportunities for PSTs to engage with the practice of teacher noticing. We analyzed how our design choices led to different evidence of the PSTs' interpretations through professional development design study methods. Findings indicate that the PSTs frequently interpret what students understood. Yet, they were more challenged by interpreting what students did not yet understand. Furthermore, we found that providing lesson goals and asking the PSTs to respond to a prompt of deciding how to respond had the potential to elicit PSTs' interpretations of what the students did not yet understand. The study highlights the interplay between task design, prompt wording, and PSTs' interpretations, which emphasizes the complexity of developing teacher noticing 

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4. Computational Classrooms: A Research-Based Approach to Designing a Computer Science Course for Elementary and Middle School Teachers

   Rivera, J; Radoff, J (March 2025, National Association for Research in Science Teaching)

   To address the complex threats to Earth's life-sustaining systems, students need to learn core concepts and practices from various disciplines, including mathematics, civics, science, and, increasingly, computer science (NRC, 2012; United Nations, 2021). Schools must therefore equip students to navigate and integrate these disciplines to tackle real-world problems. Over the past two decades, STEM educators have advocated for an interdisciplinary approach, challenging traditional barriers between subjects and emphasizing contextualized real-world issues (Hoachlander & Yanofsky, 2011; Vasquez et al., 2013; Ortiz-Revilla et al., 2020; Honey et al., 2014; Takeuchi et al., 2020). Despite extensive evidence supporting integrated approaches to STEM education, subject boundaries remain, with disciplines often taught separately and computer science and computational thinking (CS & CT) not consistently included in elementary and middle school curricula. In today's digital age, CS and CT are crucial for a well-rounded education and for addressing sustainability challenges (ESSA, 2015; NGSS Lead States, 2013; NRC, 2012). While there's consensus on the importance of introducing computational concepts and practices to elementary and middle school students, integrating them into existing curricula poses significant challenges, including how to effectively support teachers to deliver inquiry instruction confidently and competently (Ryoo, 2019). Existing frameworks and tools for teaching CS and CT often focus on maintaining fidelity to canonical concepts and formalized taxonomies rather than on practical applications (Grover & Pea, 2013; Kafai et al., 2020; Wilkerson et al., 2020). This focus can lead teachers to learn terminology without fully understanding its relevance or application in different contexts. In response, some researchers suggest using a learning sciences perspective to consider “how the complexity of everyday spaces of learning shapes what counts, and what should be counted, as ‘computational thinking’” (Wilkerson et al., 2020, p. 265). These scholars emphasize the importance of drawing on learners’ everyday experiences and problems to make computational practices more meaningful and contextually relevant for both teachers and their students. Thus, this paper aims to address the following question: How can we design learning experiences for in-service teachers that support (1) their authentic engagement with computational concepts, practices, and tools and (2) more effective integration within classroom contexts? In the limited space of this proposal, we primarily address part 1. 

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5. Computational Thinking Integration Strategy for the Urban Middle School Classroom

   https://doi.org/10.5430/irhe.v3n3p51  

   Birney, Lauren; McNamara, Denise (July 2018, International Research in Higher Education)

   This article provides an overview of the work pioneered by the consortium of collaborators in the Billion Oyster Curriculum and Community Enterprise for Restoration Science Project (BOP-CCERS). The BOP-CCERS are working to support computational thinking in the New York City public school classrooms by creating curriculum which combines:1. The Field Station Research (Oyster Restoration Stations) and data collection2. The Billion Oyster Project Digital Platform and data input and storage 3. The New York State Science Intermediate Level Learning Standards. 4. The Computer Science Teachers Association K-12 Computer Science StandardsThe integration of computational thinking in the STEM middle school classroom is showcased through the intertwining of these dimensions into a trans-disciplinary learning experience that is rich in both content and practice. Students will be able to explain real-world phenomena found in their own community and design possible solutions through the key components of computational thinking.The Curriculum and Community Enterprise for Restoration Science Project digital platform and curriculum will be the resources that provide the underpinnings of the integration of computational thinking in the STEM middle school classroom. The primary functions of the platform include the collection and housing of the data pertaining to the harbor and its component parts, both abiotic and biotic and the storage of the curriculum for both the classroom and the field stations. 

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