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1. How do undergraduate engineering students conceptualize product design? An analysis of two third‐year design courses

   https://doi.org/10.1002/jee.20468  

   Miska, Jacob W.; Mathews, Laura; Driscoll, Jessica; Hoffenson, Steven; Crimmins, Sarah; Espera, Jr., Alejandro; Pitterson, Nicole (May 2022, Journal of Engineering Education)

   Abstract BackgroundEngineering education traditionally emphasizes technical skills, sometimes at the cost of under‐preparing graduates for the real‐world engineering context. In recent decades, attempts to address this issue include increasing project‐based assignments and engineering design courses in curricula; however, a skills gap between education and industry remains. Purpose/HypothesisThis study aims to understand how undergraduate engineering students perceive product design before and after an upper‐level project‐based design course, as measured through concept maps. The purpose is to measure whether and how students account for the technical and nontechnical elements of design, as well as how a third‐year design course influences these design perceptions. Design/MethodConcept maps about product design were collected from 105 third‐year engineering students at the beginning and end of a design course. Each concept map's content and structure were quantitatively analyzed to evaluate the students' conceptual understandings and compare them across disciplines in the before and after conditions. ResultsThe analyses report on how student conceptions differ by discipline at the outset and how they changed after taking the course. Mechanical Engineering students showed a decrease in business‐related content and an increased focus on societal content, while students in the Engineering Management and Industrial and Systems Engineering programs showed an increase in business topics, specifically market‐related content. ConclusionThis study reveals how undergraduate students conceptualize product design, and specifically to what extent they consider engineering, business, and societal factors. The design courses were shown to significantly shape student conceptualizations of product design, and they did so in a way that mirrored the topics in the course syllabi. The findings offer insights into the education‐practice skills gap and may help future educators to better prepare engineering students to meet industry needs. 

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2. Characterizing First-Year Engineering Students’ Priorities and Language Use in Socio-technical Written Reflections

   https://doi.org/10.18260/1-2--48454  

   Cantilina, Kaylla; Andrews, Chelsea; Rahman, Fatima (June 2024, ASEE Conferences)

   Here's a shorter abstract for this introduction: This paper examines efforts to integrate justice perspectives throughout a first-year computing course for engineers, moving beyond traditional approaches that separate technical and social content. Funded by NSF, our redesigned course embeds justice components through weekly sociotechnical labs, readings with written reflections, justice-themed coding projects, and a final project addressing social impacts. This analysis focuses on students' weekly reflections from one course section to understand how they conceptualize bias, differential impacts, and causes of societal outcomes across different topics. Our findings offer insights for educators seeking to center justice in engineering education through integrated reflection activities rather than standalone ethics modules. 

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3. Leveraging Sustainability to Teach About Social Justice in Civil Engineering Curricula

   Siller, T.; Atadero, R. A.; Casper, A. M.; Paguyo, C. H. (June 2022, IJEE International Journal of Engineering Education)

   Sustainability is a vital interdisciplinary concept to address within engineering education. Furthermore, the natural connections that exist between sustainability and social justice provide an optimal opportunity to integrate both into curricula. We argue that engineering curricula ought to include sustainability and social justice so future engineers are trained to understand both societal and technical implications of their work, while acknowledging the challenges engineering faculty may face in conceptualizing social justice or social sustainability. We then highlight how new sustainable design rating systems, such as Envision and The Living Building Challenge, embed inclusion and social justice into their ratings and how these sustainability rating systems can help engineering faculty bring social justice into their classrooms in ways that meaningfully link to engineering content. Finally, we present two examples of how sustainability and social justice can be incorporated into the civil engineering curriculum through inclusive pedagogy and new curricula: 1) a semester-long effort to document, design, and improve the inclusive pedagogical practices in a first-year engineering course that included the theme of sustainability throughout much of the class meetings; and 2) a new assignment about the Envision rating system and the societal implications of rebuilding a major component of regional infrastructure. We conclude with recommendations that other instructors can use to begin incorporating social justice in their courses. 

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4. Board 308: Improving Students’ Sociotechnical Literacy in Engineering

   https://doi.org/10.18260/1-2--46886  

   Danahy, Ethan; Andrews, Chelsea; Cantilina, Kaylla; Cross, Jennifer (June 2024, ASEE Conferences)

   The Improving Students’ Sociotechnical Literacy in Engineering project aims to integrate social justice topics with technical knowledge in a first-year engineering course. The approach involves redesigning an existing intro to computing course with justice-based activities, supported by an Equity Learning Assistant (ELA) program. This program trains upperclass students to facilitate in-class discussions on equity and social justice. The project targets improvements in students' critical sociotechnical literacy and engineering identity. Activities include analyzing ethically complex data sets and developing equity-focused projects, while encouraging students to integrate social, economic, and political dimensions into their engineering work. This initiative spans four years (one pilot year plus three NSF-funded iterations) and involves a multidisciplinary research team of engineers and education researchers. 

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5. 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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