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1. RPPs: Love 'Em or Leave 'Em

   Bevan, Bronwyn ; Henrick, Erin ; McGee, Steven ; Dettori, Lucia ( April 2019 , ISEE Xplore)

   For the last three years the CS for All initiative at the National Science Foundation has had a call for research-practice partnership (RPP) projects. The goal of the program is to advance both knowledge and practice in creating inclusive, responsive computer science/computational thinking programs for all K-12 youth. RPPs represent an approach to research that, by design, is both more equitable and more ethical because it leverages community stakeholder experiences and perspectives to inform research questions, methods, and meaning-making. RPPs are thus potentially powerful tools for equity-oriented initiatives such as CS for All. Beginning in December 2016, the Research + Practice Collaboratory, an NSF-funded initiative based at the University of Washington, has led ten RPP development workshops for CS for All, collectively serving over 700 members of the community. At these workshops we have collected data about how the community sees itself benefiting from the adoption of RPP approaches to the work. In this experience paper we describe what we have learned about the field’s interests with respect to adopting RPP approaches to the work. 

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2. Partnering Middle School Teachers, Industry, and Academic to Bring Engineering to the Science Classroom

   Carrico, C. ; Grohs, J.R. ; Matusovich, H.M. ; Kirk, G.R. ; Schilling, M.R. ( July 2021 , 2021 ASEE Virtual Annual Conference Content Access)

   Despite limited success in broadening participation in engineering with rural and Appalachian youth, there remain challenges such as misunderstandings around engineering careers, misalignments with youth’s sociocultural background, and other environmental barriers. In addition, middle school science teachers may be unfamiliar with engineering or how to integrate engineering concepts into science lessons. Furthermore, teachers interested in incorporating engineering into their curriculum may not have the time or resources to do so. The result may be single interventions such as a professional development workshop for teachers or a career day for students. However, those are unlikely to cause major change or sustained interest development. To address these challenges, we have undertaken our NSF ITEST project titled, Virginia Tech Partnering with Educators and Engineers in Rural Schools (VT PEERS). Through this project, we sought to improve youth awareness of and preparation for engineering related careers and educational pathways. Utilizing regular engagement in engineering-aligned classroom activities and culturally relevant programming, we sought to spark an interest with some students. In addition, our project involves a partnership with teachers, school districts, and local industry to provide a holistic and, hopefully, sustainable influence. By engaging over time we aspired to promote sustainability beyond this NSF project via increased teacher confidence with engineering related activities, continued integration within their science curriculum, and continued relationships with local industry. From the 2017-2020 school years the project has been in seven schools across three rural counties. Each year a grade level was added; that is, the teachers and students from the first year remained for all three years. Year 1 included eight 6th grade science teachers, year 2 added eight 7th grade science teachers, and year 3 added three 8th grade science teachers and a career and technology teacher. The number of students increased from over 500 students in year 1 to over 2500 in year 3. Our three industry partners have remained active throughout the project. During the third and final year in the classrooms, we focused on the sustainable aspects of the project. In particular, on how the intervention support has evolved each year based on data, support requests from the school divisions, and in scaffolding “ownership” of the engineering activities. Qualitative data were used to support our understanding of teachers’ confidence to incorporate engineering into their lessons plans and how their confidence changed over time. Noteworthy, our student data analysis resulted in an instrument change for the third year; however due to COVID, pre and post data was limited to schools who taught on a semester basis. Throughout the project we have utilized the ITEST STEM Workforce Education Helix model to support a pragmatic approach of our research informing our practice to enable an “iterative relationship between STEM content development and STEM career development activities… within the cultural context of schools, with teachers supported by professional development, and through programs supported by effective partnerships.” For example, over the course of the project, scaffolding from the University leading interventions to teachers leading interventions occurred. 

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3. Interpersonal Interactions that Foster Inclusion: Building Supports for Diversity in Engineering Teams

   Rodríguez-Simmonds, Héctor E. ; Jackson, Benjamin P. ; Pearson, Nelson S. ; Langus, Tara C. ; Major, Justin C. ; Kirn, Adam ; Godwin, Allison ( January 2018 , ASEE annual conference & exposition)

   Teaming is a core part of engineering education, especially in the first and last years of engineering when project work is a prevalent focus. The literature on the effects of working in diverse teams is mixed. Negative findings include decreased affect, increased frustration, and sustained conflict in teams. Positive findings include increased productivity, production of high quality products, and divergent-thinking and idea generation. Given these mixed findings, it becomes important to not only understand the practical outputs of working in diverse teams, but also how the experience of working in diverse teams influences whether students see themselves as engineers and whether or not they feel they belong in engineering. Our project, Building Supports for Diversity through Engineering Teams, investigates how students’ attitudes towards diversity influence how students experience work in diverse teams through addressing two main research questions: 1) What changes occur in students’ diversity sensitivity, multicultural effectiveness, and engineering practices as a result of working in diverse teams? 2) How do students’ perceptions of diversity, affect, and engineering practices change because of working on diverse teams? Using a multi-method approach, we deployed survey instruments to determine changes in student’s attitudes about teaming, diversity sensitivity, and openness attitudes. We also observed students working in teams and interviewed these students about their perceptions of diversity and experiences in their teams. Preliminary results of the quantitative phase show that variance in students’ attitudes about diversity significantly increase over the semester, further reflecting the mixed results that have been seen previously in the literature. Additionally, Social Network Analysis was used to characterize the social structure practices of a multi-section, large-enrollment first-year engineering course. This reveals the underlying social structure of the environment, its inclusiveness, and how diverse students work with others on engineering. Initial results indicate that students are included in social networks regardless of gender and race. Preliminary results of the qualitative phase, using Interpretive Phenomenological Analysis, have yielded relationships between student’s definitions, valuation, and enactment of diversity in engineering spaces. Individual student’s incoming attitudes of diversity and previous experiences interact with practical needs in first-year engineering classrooms to create different microclimates within each team. These microclimates depict tensions between what instructors emphasize about diversity, stereotypes of engineering as focused on technical instead of social skills, and pragmatic forces of “getting the job done.” This knowledge can help explain some of the complexity behind the conflicting literature on diversity in teams. Ultimately, this research can help us understand how to build inclusive and diverse environments that guide students to learn how to understand their own complex relationship, understanding, and enactment of diversity in engineering. By understanding how students make sense of diversity in engineering spaces, educators and researchers can figure out how to introduce these concepts in relevant ways so that students can inclusively meet the grand challenges in engineering. This curriculum integration, in turn, can improve team interactions and the climate of engineering for underrepresented groups. 

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4. Teacher’s experiences co-designing neurodiverse pedagogies for computational thinking

   Vasquez, A. M. ( April 2023 , American Educational Research Association (AERA) Annual Meeting 2023)

   The purpose of this research was to study the experiences of middle-school teachers of autistic students during the co-design of neurodiverse pedagogies for computational thinking (CT) within the context of a research practitioner partnership (RPP). This knowledge building partnership was founded on the neurodiversity paradigm and challenges the assumption that individuals with disabilities are exceptions for which accommodations must be made. Neurodiversity, here, is viewed as the natural variation of neurological differences and as such is proposed to be the baseline in every educational setting (Silberman, 2016; Walker, n.d.). When neurodiversity is seen as a baseline for an educational community, the focus is on educating diverse (whole) individuals rather than planning and teaching a standard computational thinking curriculum, while adding accommodations or adaptations to meet the needs of individual students. Our paper presents the results from a critical event analysis using qualitative data collected during the first year of a three-year mixed methods study, which includes teacher workshop mini-interviews and teacher embodied interviews. In this study, we ask: How do teachers experience the co-designing of neurodiverse pedagogies for computational thinking in a research practitioner partnership? And, how do these teachers modify and diversify their teaching practices of CT? 

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5. Middle school teachers’ self-efficacy in teaching computer science and digital literacy: Impact of the CS Pathways RPP professional development program

   https://doi.org/DOI:10.13140/RG.2.2.31416.26887  

   Bausch, G. ; Ni, L. ; Martin, F. ; Hsu, H. ; Feliciano, B ( October 2021 , The intersection of RPPs and BPC in CS education: A culmination of papers from the RPPforCS Community)

   Background: Researcher-practitioner partnerships (RPPs) have gained increasing prominence within education, since they are crucial for identifying partners’ problems of practice and seeking solutions for improving district (or school) problems. The CS Pathways RPP project brought together researchers and practitioners, including middle school teachers and administrators from three urban school districts, to build teachers’ capacity to implement an inclusive computer science and digital literacy (CSDL) curriculum for all students in their middle schools. Objective: This study explored the teachers’ self-efficacy development in teaching a middle school CSDL curriculum under the project’s RPP framework. The ultimate goal was to gain insights into how the project’s RPP framework and its professional development (PD) program supported teachers’ self-efficacy development, in particular its challenges and success of the partnership. Method: Teacher participants attended the first-year PD program and were surveyed and/or interviewed about their self-efficacy in teaching CSDL curriculum, spanning topics ranging from digital literacy skills to app creation ability and curriculum implementation. Both survey and interview data were collected and analyzed using mixed methods 1) to examine the reach of the RPP PD program in terms of teachers’ self-efficacy; 2) to produce insightful understandings of the PD program impact on the project’s goal of building teachers’ self-efficacy. Results and Discussion: We reported the teachers’ self-efficacy profiles based on the survey data. A post-survey indicated that a majority of the teachers have high self-efficacy in teaching the CSDL curriculum addressed by the RPP PD program. Our analysis identified five critical benefits the project’s RPP PD program provided, namely collaborative efforts on resource and infrastructure building, content and pedagogical knowledge growth, collaboration and communication, and building teacher identity. All five features have shown direct impacts on teachers' self-efficacy. The study also reported teachers’ perceptions on the challenges they faced and potential areas for improvements. These findings indicate some important features of an effective PD program, informing the primary design of an RPP CS PD program. 

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