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1. Moving Toward Transdisciplinary Learning Around Topics of Convergence: Is it really Possible in Higher Education Today?

   Strimel, G.; Pruim, D.; Briller, S.; Martinez, R.; Lucas, D.; Kelley, T.; Sohn, J. (June 2023, Review directory American Society for Engineering Education)

   There have been numerous demands for enhancements in the way undergraduate learning occurs today, especially at a time when the value of higher education continues to be called into question (The Boyer 2030 Commission, 2022). One type of demand has been for the increased integration of subjects/disciplines around relevant issues/topics—with a more recent trend of seeking transdisciplinary learning experiences for students (Sheets, 2016; American Association for the Advancement of Science, 2019). Transdisciplinary learning can be viewed as the holistic way of working equally across disciplines to transcend their own disciplinary boundaries to form new conceptual understandings as well as develop new ways in which to address complex topics or challenges (Ertas, Maxwell, Rainey, & Tanik, 2003; Park & Son, 2010). This transdisciplinary approach can be important as humanity’s problems are not typically discipline specific and require the convergence of competencies to lead to innovative thinking across fields of study. However, higher education continues to be siloed which makes the authentic teaching of converging topics, such as innovation, human-technology interactions, climate concerns, or harnessing the data revolution, organizationally difficult (Birx, 2019; Serdyukov, 2017). For example, working across a university’s academic units to collaboratively teach, or co-teach, around topics of convergence are likely to be rejected by the university systems that have been built upon longstanding traditions. While disciplinary expertise is necessary and one of higher education’s strengths, the structures and academic rigidity that come along with the disciplinary silos can prevent modifications/improvements to the roles of academic units/disciplines that could better prepare students for the future of both work and learning. The balancing of disciplinary structure with transdisciplinary approaches to solving problems and learning is a challenge that must be persistently addressed. These institutional challenges will only continue to limit universities seeking toward scaling transdisciplinary programs and experimenting with novel ways to enhance the value of higher education for students and society. This then restricts innovations to teaching and also hinders the sharing of important practices across disciplines. To address these concerns, a National Science Foundation Improving Undergraduate STEM Education project team, which is the topic of this paper, has set the goal of developing/implementing/testing an authentically transdisciplinary, and scalable educational model in an effort to help guide the transformation of traditional undergraduate learning to span academics silos. This educational model, referred to as the Mission, Meaning, Making (M3) program, is specifically focused on teaching the crosscutting practices of innovation by a) implementing co-teaching and co-learning from faculty and students across different academic units/colleges as well as b) offering learning experiences spanning multiple semesters that immerse students in a community that can nourish both their learning and innovative ideas. As a collaborative initiative, the M3 program is designed to synergize key strengths of an institution’s engineering/technology, liberal arts, and business colleges/units to create a transformative undergraduate experience focused on the pursuit of innovation—one that reaches the broader campus community, regardless of students’ backgrounds or majors. Throughout the development of this model, research was conducted to help identify institutional barriers toward creating such a cross-college program at a research-intensive public university along with uncovering ways in which to address these barriers. While data can show how students value and enjoy transdisciplinary experiences, universities are not likely to be structured in a way to support these educational initiatives and they will face challenges throughout their lifespan. These challenges can result from administration turnover whereas mutual agreements across colleges may then vanish, continued disputes over academic territory, and challenges over resource allotments. Essentially, there may be little to no incentives for academic departments to engage in transdisciplinary programming within the existing structures of higher education. However, some insights and practices have emerged from this research project that can be useful in moving toward transdisciplinary learning around topics of convergence. Accordingly, the paper will highlight features of an educational model that spans disciplines along with the workarounds to current institutional barriers. This paper will also provide lessons learned related to 1) the potential pitfalls with educational programming becoming “un-disciplinary” rather than transdisciplinary, 2) ways in which to incentivize departments/faculty to engage in transdisciplinary efforts, and 3) new structures within higher education that can be used to help faculty/students/staff to more easily converge to increase access to learning across academic boundaries. 

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2. Immersive In‐Person Field Courses during the Pandemic: Minimizing Risk while Maximizing Efficacy

   https://doi.org/10.1002/bes2.1984  

   McLaughlin, John (March 2022, The Bulletin of the Ecological Society of America)

   Abstract Field courses can provide formative experiences that also reduce disparities in STEM education. Impacts of the ongoing COVID‐19 pandemic on‐field programs have been particularly severe, as many institutions shifted to online instruction. Some courses retained in‐person field experiences during the pandemic, and achieved high student learning outcomes. Here, I describe an approach to mitigating risk of COVID‐19 and other hazards during expedition‐based field courses, and student learning outcomes achieved using that approach. I applied comprehensive risk management to in‐person field expeditions that treated COVID‐19 as a hazard, requiring mitigation to maintain an acceptable low level of risk. Prior to broad availability of COVID‐19 vaccines, we applied a coronavirus‐free “bubble” strategy in which all participants passed a COVID‐19 PCR test immediately before departure and then avoided contact with people outside our bubble. In the future, vaccination can reduce risk further. We implemented additional safety factors to reduce risk of incidents that could require evacuation into medical facilities overloaded with COVID‐19 patients. The courses were successful: we had no infections or other serious incidents and student learning outcomes were transformative. The approach provides a model for conducting immersive field courses during the pandemic and beyond. Several field course networks are implementing similar approaches to restore valuable field education opportunities that have declined during the pandemic. 

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3. High-Impact Teaching Practices in Higher Education: Understanding Barriers, Concerns, and Obstacles to Their Adoption

   https://doi.org/10.3390/higheredu3010006  

   VanWyngaarden, Kristin; Pelton, Julie A.; Oquendo, Pamela Martínez; Moore, Christopher (March 2024, Trends in Higher Education)

   This research explores the barriers, concerns, and obstacles undergraduate STEM educators face when implementing high-impact teaching practices (HIPs), the application of which may improve student learning outcomes. Because our study took place during the COVID-19 pandemic, our results also shed light on the unique challenges of utilizing HIPs in asynchronous online-learning environments. Thirteen undergraduate instructors were interviewed about their current teaching practices in order to identify barriers to or support for adopting HIPs. Data collected through semi-structured interviews revealed administrative and financial restraints as barriers to effective teaching which have been found in previous research. A number of new and unique obstacles emerged out of teaching remotely or online during the pandemic, including a heightened concern over the instructor’s ability to connect with students and engage in the best teaching practices. This research extends our current understanding of barriers and concerns about adopting HIPs in undergraduate STEM courses because of the unique perceived threats that emerged during the pandemic. We identify strategies to equip faculty with the support they need to provide equitable learning experiences, including access to consultants who support curriculum development and implementation in the classroom, ongoing educational coaching, and increased access to professional-development opportunities and a community of inquiry to discuss teaching strategies. 

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4. I will teach you here or there, I will try to teach you anywhere: perceived supports and barriers for emergency remote teaching during the COVID-19 pandemic

   https://doi.org/10.1186/s40594-022-00335-1  

   Donham, Cristine; Barron, Hillary A.; Alkhouri, Jourjina Subih; Changaran Kumarath, Maya; Alejandro, Wesley; Menke, Erik; Kranzfelder, Petra (February 2022, International Journal of STEM Education)

   Abstract BackgroundDue to the COVID-19 pandemic, many universities moved to emergency remote teaching (ERT). This allowed institutions to continue their instruction despite not being in person. However, ERT is not without consequences. For example, students may have inadequate technological supports, such as reliable internet and computers. Students may also have poor learning environments at home and may need to find added employment to support their families. In addition, there are consequences to faculty. It has been shown that female instructors are more disproportionately impacted in terms of mental health issues and increased domestic labor. This research aims to investigate instructors’ and students’ perceptions of their transition to ERT. Specifically, during the transition to ERT at a research-intensive, Minority-Serving Institution (MSI), we wanted to: (1) Identify supports and barriers experienced by instructors and students. (2) Compare instructors’ experiences with the students’ experiences. (3) Explore these supports and barriers within the context ofsocial presence,teaching presence, and/orcognitive presenceas well as how these supports and barriers relate toscaffoldingin STEM courses. ResultsInstructors identified twice as many barriers as supports in their teaching during the transition to ERT and identified casual and formal conversations with colleagues as valuable supports. Emerging categories for barriers consisted of academic integrity concerns as well as technological difficulties. Similarly, students identified more barriers than supports in their learning during the transition to ERT. More specifically, students described pre-existing course structure, classroom technology, and community as best supporting their learning. Barriers that challenged student learning included classroom environment, student availability, and student emotion and comfort. ConclusionsTogether, this research will help us understand supports and barriers to teaching and learning during the transition to ERT. This understanding can help us better plan and prepare for future emergencies, particularly at MSIs, where improved communication and increased access to resources for both students and instructors are key. 

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5. Chapter 12: Teaching in the field

   https://doi.org/10.4324/9781003342953-14  

   Gamble, Douglas W; Haproff, Peter J; Wu, Chen (November 2024, Routledge)

   Solem, Michael; Foote, Kenneth; O'Lear, Shannon; Eaves, LaToya; Lee, Jongwon (Ed.)

   One of the most rewarding and enjoyable aspects of teaching in geography and geoscience is field instruction. Designing and implementing field experiences can be both an exciting and overwhelming prospect. The reality is that field instruction requires diligent preparation, both in and outside the classroom, if it is to provide successful and meaningful learning experiences. Many geographers and geoscientists are committed to experiential, field‑based learning and have written about both the practical and theoretical aspects of successfully teaching in the field. This chapter offers a summary of this helpful literature, while also discussing some of the authors’ experiences of “lessons learned” from teaching in the field, and the impact of the recent COVID‑19 pandemic on field instruction. 

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