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1. Toward a justice‐centered ambitious teaching framework: Shaping ambitious science teaching to be culturally sustaining and productive in a rural context

   https://doi.org/10.1002/tea.21917  

   Luehmann, April; Zhang, Yang; Boyle, Heather; Tulbert, Eve; Merliss, Gena; Sullivan, Kyle (November 2023, Journal of Research in Science Teaching)

   Abstract We find ourselves at a time when the need for transformation in science education is aligning with opportunity. Significant science education resources, namely the Next Generation Science Standards (NGSS) and the Ambitious Science Teaching (AST) framework, need an intentional aim of centering social justice for minoritized communities and youth as well as practices to enact it. While NGSS and AST provide concrete guidelines to support deep learning, revisions are needed to explicitly promote social justice. In this study, we sought to understand how a commitment to social justice, operationalized through culturally sustaining pedagogy (Paris, Culturally sustaining pedagogies and our futures.The Educational Forum, 2021; 85, pp. 364–376), might shape the AST framework to promote more critical versions of teaching science for equity. Through a qualitative multi‐case study, we observed three preservice teacher teams engaged in planning, teaching, and debriefing a 6‐day summer camp in a rural community. Findings showed that teachers shaped the AST sets of practices in ways that sustained local culture and addressed equity aims: anchoring scientific study in phenomena important to community stakeholders; using legitimizing students' stories by both using them to plan the following lessons and as data for scientific argumentation; introducing local community members as scientific experts, ultimately supporting a new sense of pride and advocacy for their community; and supporting students in publicly communicating their developing scientific expertise to community stakeholders. In shaping the AST framework through culturally sustaining pedagogy, teachers made notable investments: developing local networks; learning about local geography, history, and culture; building relationships with students; adapting lessons to incorporate students' ideas; connecting with community stakeholders to build scientific collaborations; and preparing to share their work publicly with the community. Using these findings, we offer a justice‐centered ambitious science teaching (JuST) framework that can deliver the benefits of a framework of practices while also engaging in the necessarily more critical elements of equity work. 

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2. Transforming STEM Instruction Through SocioScientific Issues Focused Professional Development

   Johnson, Joseph; Mathers, Becky; Marco-Bujosa, Lisa; Ialacci, Gabrielle (June 2024, International journal on new trends in education and their implications)

   This study reports the findings of a two-year intensive professional development (PD) program situated in the northeastern United States for secondary mathematics and science teachers to support them in transforming their STEM instruction to incorporate SocioScientific Issues (SSI). This PD focused on developing units of study that integrated student-centered, authentic learning experiences grounded in social justice issues. Findings indicate that after participation in the USTRIVE project, teachers displayed growth in their ability to incorporate components of the instructional framework for SSI introduced in the PD into their teaching. This is consistent with previous research that SSI-focused PD can increase teachers’ knowledge of, and teaching practices toward SSI, resulting in more meaningful STEM learning experiences for students. As such, the USTRIVE PD model and framework may provide a useful guide for other SSI and social justice PD programs. Connections of these findings to student engagement, teachers learning, and challenges encountered in SSI implementation are explored. 

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3. Socioscientific issues: promoting science teachers’ pedagogy on social justice

   https://doi.org/10.1186/s43031-024-00118-4  

   Macalalag, Jr., Augusto_Z; Kaufmann, Alan; Van_Meter, Benjamin; Ricketts, Aden; Liao, Erica; Ialacci, Gabrielle (December 2024, Disciplinary and Interdisciplinary Science Education Research)

   Abstract Socioscientific issues (SSI) are problems involving the deliberate use of scientific topics that require students to engage in dialogue, discussion, and debate. The purpose of this project is to utilize issues that are personally meaningful and engaging to students, require the use of evidence-based reasoning, and provide a context for scientific information. Social justice is the pursuit of equity and fairness in society by ensuring that all individuals have opportunities to challenge and address inequalities and injustices to create a more just and equitable society for all (Killen et al. Human Development 65:257–269, 2021). By connecting science, technology, engineering, and mathematics (STEM) concepts to personally meaningful contexts, SSI can empower students to consider how STEM-based issues reflect moral principles and elements of virtue in their own lives and the world around them (Zeidler et al. Science Education 89:357–377, 2005). We employed a qualitative research design to answer the following questions: (1) In what ways, if any, did teachers help students grow their knowledge and practices on social justice through socioscientific issues? (2) In teachers’ perceptions, what components of SSI did students learn and what are their challenges? (3) In teachers’ perceptions, what are students’ stances on social justice? After completing the first year and second-year professional development programs, grades 6–12 STEM teachers were asked to complete a reflection on classroom artifacts. Teachers were asked to select student artifacts (e.g. assignments, projects, essays, videos, etc.) that they thought exemplified the students’ learning of SSI and stance on social justice. Based on 21 teacher-submitted examples of exemplar student work, we saw the following example pedagogies to engage their students on social justice: (a) making connections to real-world experiences, (b) developing a community project, (c) examining social injustice, and (d) developing an agency to influence/make changes. According to teachers, the most challenging SSI for students was elucidating their own position/solution, closely followed by employing reflective scientific skepticism. Moreover, the students exemplified reflexivity, metacognition, authentic activity, and dialogic conversation. Using SSI in classrooms allows students to tackle real-world problems, blending science and societal concerns. This approach boosts understanding of scientific concepts and their relevance to society. Identifying methods like real-world connections and examining social injustice helps integrate social justice themes into science education through SSI. Overall, SSI promotes interdisciplinary learning, critical thinking, and informed decision-making, enriching science education socially. This study highlights the value of integrating SSI in science education to engage students with social justice. 

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4. From Professional Development to Pedagogy: Examining How Computer Science Teachers Conceptualize and Apply Culturally Responsive Pedagogy

   Codding, D.; Alkhateeb, B.; Mouza, C; Pollock, L. (January 2021, Journal of technology and teacher education)

   The field of computer science continues to lack diverse representation from women and racially minoritized individuals. One way to address the discrepancies in representation is through systematic changes in computer science education from a young age. Pedagogical and instructional changes are needed to promote meaningful and equitable learning that engages students with rigorous and inclusive curricula. We developed an equity-focused professional development program for teachers that promotes culturally responsive pedagogy in the context of computer science education. This study provides an overview of our culturally responsive framework and a qualitative examination of how teachers (n=9) conceptualized and applied culturally responsive pedagogy in their classrooms. Drawing from grounded theory and lesson assessment rubrics, we developed a codebook to analyze teacher interviews, lesson plans, and questionnaire responses. Findings revealed that, following their participation in professional development, teachers were consistently planning to implement a wide range of culturally responsive instructional and pedagogical practices capable of promoting diversity, equity, and inclusion in computer science education. 

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5. From professional development to pedagogy: An examination of computer science teachers’ culturally responsive instructional practices

   Codding, D.; Alkhateeb, B.; Mouza, C.; Pollock, L. (January 2021, Journal of technology and teacher education)

   The field of computer science continues to lack diverse representation from women and racially minoritized individuals. One way to address the discrepancies in representation is through systematic changes in computer science education from a young age. Pedagogical and instructional changes are needed to promote meaningful and equitable learning that engages students with rigorous and inclusive curricula. We developed an equity-focused professional development program for teachers that promotes culturally responsive pedagogy in the context of computer science education. This study provides an overview of our culturally responsive framework and a qualitative examination of how teachers (n=9) conceptualized and applied culturally responsive pedagogy in their classrooms. Drawing from grounded theory and lesson assessment rubrics, we developed a codebook to analyze teacher interviews, lesson plans, and questionnaire responses. Findings revealed that, following their participation in professional development, teachers were consistently planning to implement a wide range of culturally responsive instructional and pedagogical practices capable of promoting diversity, equity, and inclusion in computer science education. 

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