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1. Visual Literacy Intervention for Improving Undergraduate Student Critical Thinking of Global Sustainability Issues

   https://doi.org/10.3390/su122310209  

   Krejci, Sarah E.; Ramroop-Butts, Shirma; Torres, Hector N.; Isokpehi, Raphael D. (December 2020, Sustainability)

   null (Ed.)

   The promotion of global sustainability within environmental science courses requires a paradigm switch from knowledge-based teaching to teaching that stimulates higher-order cognitive skills. Non-major undergraduate science courses, such as environmental science, promote critical thinking in students in order to improve the uptake of scientific information and develop the rational decision making used to make more informed decisions. Science, engineering, technology and mathematics (STEM) courses rely extensively on visuals in lectures, readings and homework to improve knowledge. However, undergraduate students do not automatically acquire visual literacy and a lack of intervention from instructors could be limiting academic success. In this study, a visual literacy intervention was developed and tested in the face-to-face (FTF) and online sections of an undergraduate non-major Introduction to Environmental Science course. The intervention was designed to test and improve visual literacy at three levels: (1) elementary—identifying values; (2) intermediate—identifying trends; and (3) advanced—using the data to make projections or conclusions. Students demonstrated a significant difference in their ability to answer elementary and advanced visual literacy questions in both course sections in the pre-test and post-test. Students in the face-to-face course had significantly higher exam scores and higher median assessment scores compared to sections without a visual literacy intervention. The online section did not show significant improvements in visual literacy or academic success due to a lack of reinforcement of visual literacy following the initial intervention. The visual literacy intervention shows promising results in improving student academic success and should be considered for implementation in other general education STEM courses. 

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2. Place-Based Experiential Learning: A Pathway to Sustainability and Environmental Literacy

   https://doi.org/10.3102/1893023  

   Sorge, B.H.; Fore, G.A.; Williamson, F.A.; Angstmann, J.L. (April 2022, 2022 Annual Meeting of the American Educational Research Association)

   When implemented effectively, Place-Based Experiential Learning (PBEL) pedagogies have been shown through different studies to enhance student content knowledge, course engagement, critical thinking skills, and civic-mindedness. This research followed 10 semester long university courses, during one academic year, implementing PBEL pedagogies with a focus on urban farming. Courses came from a wide array of disciplines including courses focused on science, technology, engineering, or mathematics as well as many non-STEM courses. Students completed pre- and post-assessments to measure change in civic-mindedness, place attachment, situated sustainability meaning-making, and environmental scientific literacy. Statistically significant positive change with small to moderate effect sizes were found in student’s environmental scientific literacy, situated sustainability meaning-making, place attachment, and civic-mindedness. 

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3. AI literacy as a core component of AI education

   https://doi.org/10.1002/aaai.70007  

   Tadimalla, Sri Yash; Maher, Mary Lou (June 2025, AI Magazine)

   Abstract As generative artificial intelligence (AI) becomes increasingly integrated into society and education, more institutions are implementing AI usage policies and offering introductory AI courses. These courses, however, should not replicate the technical focus typically found in introductory computer science (CS) courses like CS1 and CS2. In this paper, we use an adjustable, interdisciplinary socio‐technical AI literacy framework to design and present an introductory AI literacy course. We present a refined version of this framework informed by the teaching of a 1‐credit general education AI literacy course (primarily for freshmen and first‐year students from various majors), a 3‐credit course for CS majors at all levels, and a summer camp for high school students. Drawing from these teaching experiences and the evolving research landscape, we propose an introductory AI literacy course design framework structured around four cross‐cutting pillars. These pillars encompass (1) understanding the scope and technical dimensions of AI technologies, (2) learning how to interact with (generative) AI technologies, (3) applying principles of critical, ethical, and responsible AI usage, and (4) analyzing implications of AI on society. We posit that achieving AI literacy is essential for all students, those pursuing AI‐related careers, and those following other educational or professional paths. This introductory course, positioned at the beginning of a program, creates a foundation for ongoing and advanced AI education. The course design approach is presented as a series of modules and subtopics under each pillar. We emphasize the importance of thoughtful instructional design, including pedagogy, expected learning outcomes, and assessment strategies. This approach not only integrates social and technical learning but also democratizes AI education across diverse student populations and equips all learners with the socio‐technical, multidisciplinary perspectives necessary to navigate and shape the ethical future of AI. 

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4. Implementation of Immersive Classroom Simulation Activities in a Mathematics Methods Course and a Life and Environmental Science Course

   Lee, C.W; Lee, T.D.; Castles, R.; Dickerson, D.; Fales, H.; Wilson, C.M. (December 2018, Journal of interdisciplinary teacher leadership)

   This study investigated the influence of immersive classroom simulation activities on the development of elementary pre-service teachers in two separate mathematics and science education courses that simultaneously focus on pedagogy and content. Participants submitted written personal reflections about their teaching experiences using the immersive classroom simulation activities. These reflections were analyzed for common emergent themes within and across courses. The participants discussed the benefits of the immersive classroom simulation activities in their written personal reflections. They viewed the experience as helpful in developing their skills as a practicing teacher in mathematics and science. Specifically, participants identified three sub-themes including: (a) the immersive classroom simulation activities as being beneficial by providing more authentic real-life teaching experiences than those experienced during peer-group teaching activities; (b) the importance of holding complete and appropriate understandings of content when teaching mathematics and science; and (c) the role of deep content knowledge in the process of developing high quality questions for students. This study has shown immersive classroom simulation activities to be a viable alternative for teacher education programs to engage elementary pre- service teachers in developing skills regarding classroom mathematics and science discourse. 

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5. 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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