More Like this

1. Assessing Interdisciplinary Competency in the Disaster Resilience and Risk Management Graduate Program using Concept Maps

   Deters, J. R. ; Paretti, M. C. ; Zobel, C. ; Cowell, M. ; Irish, J. L. ( June 2019 , 2019 ASEE Annual Conference and Exposition)

   Concept maps have emerged as a valid and reliable method for assessing deep conceptual understanding in engineering education within disciplines as well as interdisciplinary knowledge integration across disciplines. Most work on concept maps, however, focuses on undergraduates. In this paper, we use concept maps to examine changes in graduate students’ conceptual understanding and knowledge integration resulting from an interdisciplinary graduate program. Our study context is pair of foundational, team-taught courses in an interdisciplinary Disaster Resilience and Risk Management (DRRM) graduate program. The courses include a 3-hour research course and a 1-hour seminar that aim to build student understanding within and across Urban Affairs and Planning, Civil and Environmental Engineering, Geosciences, and Business Information Technology. The courses introduce core principles of DRRM and relevant research methods in these disciplines, and drive students to understand the intersections of these disciplines in the context of planning for and responding to natural and human-made disasters. To understand graduate student growth from disciplinary-based to interdisciplinary scholars, we pose the research questions: 1) In what ways do graduate students’ understandings of DRRM change as a result of their introduction to an interdisciplinary graduate research program? and 2) To what extent and in what ways do conceptmore »maps serve as a tool to capture interdisciplinary learning in this context? Data includes pre/post concept maps centered on disaster resilience and risk management, a one-page explanation of the post-concept map, and ethnographic field notes gathered from class and faculty meetings. Pre-concept maps were collected on the first day of class; post-concept maps will be collected as part of the final course assignment. We assess the students’ concept maps for depth of conceptual understanding within disciplines and interdisciplinary competency across disciplines, using the field notes to provide explanatory context. The results presented in this paper support the inclusion of an explanation component to concept maps, and also suggest that concept maps alone may not be the best measure of student understanding of concepts within and across disciplines in this specific context. If similar programs wish to use concept maps as an assessment method, we suggest the inclusion of an explanation component and suggest providing explicit instructions that specify the intended audience. We also suggest using a holistic scoring method, as it is more likely to capture nuances in the concept maps than traditional scoring methods, which focus solely on counting factors like hierarchies and number of cross-links.« less
2. Promoting pedagogical change around writing: Observations of discursive turbulence

   Ware, Ryan ; Mericle, Megan E. ; Prior, Paul ; Gallagher, John R. ; Popovics, John S. ; Elliott, Celia M. ; Cooper, Lance ; Zilles, Julie L. ( January 2022 , ASEE Annual Conference proceedings)

   Our work aims to support engineering and science faculty in adapting core concepts and best practices from writing studies and technical communication for their courses. We also study the effectiveness of varied supports, with an aim of improving the diffusion of effective pedagogies. Our Writing Across Engineering and Science (WAES) program includes a semester-long faculty learning community, followed by sustained mentoring, during which faculty and graduate students from our multidisciplinary team work with mentees to develop and implement new pedagogies and course materials. For graduate students, we developed an engineering course focused on engineering and science writing practices and pedagogies. This paper focuses on one key finding from our analysis: discussions about writing practices involving people from different disciplines often involve irregular and sporadic bumpiness through which foundational changes can emerge. We call this phenomenon discursive turbulence. In our experience, signs of discursive turbulence include affective intensity and co- existing contradictory beliefs. We share four examples to illustrate ways in which discursive turbulence appears, drawn from people with varying degrees and types of engagement with our transdisciplinary work: i) project team members, ii) a faculty mentee, iii) faculty who participated in a focus group on disciplinary writing goals, and iv)more »engineering graduate students who took our class on writing practice and pedagogy. Discursive turbulence now informs our mentoring approach. It can be generative as well as challenging. Importantly, it takes time to resolve, suggesting the utility of sustained mentoring during pedagogical change.« less
3. Developing a Collaborative Undergraduate STEM Program in Resilient and Sustainable Infrastructure

   Lopez del Puerto, C. ( June 2019 , 2019 ASEE Annual Conference & Exposition)

   After a natural disaster, multiple disciplines need to come together to rebuild the damaged infrastructure using new paradigms. For instance, urgent restoration of services demand to abridge the projects’ schedule and provide innovative solutions, thus making collaboration and integration essential for the project’s success. Commonly, the academic preparation of scholars on infrastructure-related disciplines takes place in isolated professional domains, rarely tackling interdisciplinary problems and/or learn from the systematic research of previous experiences. In Puerto Rico, the aftermath of Hurricanes Irma and Maria has heightened awareness regarding the education on infrastructure-related disciplines to provide transdisciplinary solutions to pertinent complex challenges. This taxing context compels the academia to train a new cadre of professionals properly prepared in those STEM disciplines. Further, current public awareness of the vulnerability of the existing infrastructure creates an opportunity to recruit and prepare students to become those much-needed professionals. The present work offers the conceptual framework of a collaborative effort among Architecture, Engineering, and Construction (AEC) to develop an interdisciplinary program in resilient and sustainable infrastructure. The framework includes the development of transformational pedagogic interventions and changes that will challenge the disciplinary splits among AEC. The framework targets values and skills for inter and transdisciplinary problem solving,more »as well as helps smooth the transition from academic education to professional practice. To implement the initiative, the project created a collaborative platform among three campuses of the University of Puerto Rico System. Each of these campuses offers a different educational component relevant to the enriching educational initiative. We expect this approach to create a new breed of professionals ready to face the challenges posed for the development of robust infrastructure. The strategy fosters readiness in environmental design in engineering and construction through evidence-based design and inter/transdisciplinary problem solving. Thus, this research contributes to the body of knowledge by presenting a collaborative effort to train future professionals to design and build a robust infrastructure that can overcome the impact of major natural catastrophes.« less
4. Developing a Collaborative Undergraduate STEM Program in Resilient and Sustainable Infrastructure

   Lopez del Puerto, Carla ; Cavallin, Humberto ; Perdomo, José ; Muñoz, Jonathan ; Suarez, Oscar Marcelo ; Andrade, Fabio ( June 2019 , Review & directory - American Society for Engineering Education)

   After a natural disaster, multiple disciplines need to come together to rebuild the damaged infrastructure using new paradigms. For instance, urgent restoration of services demand to abridge the projects’ schedule and provide innovative solutions, thus making collaboration and integration essential for the project’s success. Commonly, the academic preparation of scholars on infrastructure-related disciplines takes place in isolated professional domains, rarely tackling interdisciplinary problems and/or learn from the systematic research of previous experiences. In Puerto Rico, the aftermath of Hurricanes Irma and Maria has heightened awareness regarding the education on infrastructure-related disciplines to provide transdisciplinary solutions to pertinent complex challenges. This taxing context compels the academia to train a new cadre of professionals properly prepared in those STEM disciplines. Further, current public awareness of the vulnerability of the existing infrastructure creates an opportunity to recruit and prepare students to become those much-needed professionals. The present work offers the conceptual framework of a collaborative effort among Architecture, Engineering, and Construction (AEC) to develop an interdisciplinary program in resilient and sustainable infrastructure. The framework includes the development of transformational pedagogic interventions and changes that will challenge the disciplinary splits among AEC. The framework targets values and skills for inter and transdisciplinary problem solving,more »as well as helps smooth the transition from academic education to professional practice. To implement the initiative, the project created a collaborative platform among three campuses of the University of Puerto Rico System. Each of these campuses offers a different educational component relevant to the enriching educational initiative. We expect this approach to create a new breed of professionals ready to face the challenges posed for the development of robust infrastructure. The strategy fosters readiness in environmental design in engineering and construction through evidence-based design and inter/transdisciplinary problem solving. Thus, this research contributes to the body of knowledge by presenting a collaborative effort to train future professionals to design and build a robust infrastructure that can overcome the impact of major natural catastrophes.« less
5. Introducing Innovation to First-Year STEM Students through an Intercession Course

   https://doi.org/10.18260/1-2-1153-38332  

   Schubert, Karl D. ; Massey, Leslie B. ; Gattis, Carol S. ( November 2021 , 2021 ASEE Midwest Section Conference Proceedings)

   Innovation training is considered critical for the future of our country, yet despite the important role, opportunities for students to develop innovation skills are limited. For STEM students, training in innovation principles and processes are frequently extra curricular pursuits, such as unpaid internships with start up organizations, shadowing innovation professionals, or obtaining an additional business degree or minor covering innovation principles. The National Science Foundation has funded the authors with a Science, Technology, Engineering and Mathematics (S STEM) grant to provide scholarships combined with research on best practices for recruitment, retention, and development of innovation skills for a diverse group of low income undergraduate students. Students in the program come from STEM disciplines in engineering and the physical sciences however, business students are also integrated into innovation courses although they are not funded by the S STEM grant Design, development, and implementation of the grant funded program’s first innovation related course, a 2 week fall intercession course will be presented Th is first year course is designed to provide the students with an introduction to innovation, develop and nurture the students’ innovation mindset and skills, and also help the students’ successful transition to college. The first-year two-week intercession course wasmore »designed and developed with two credit hours focusing on content related to innovation and one credit hour focusing on student success topics. The significant academic course components included: 1) interactive active-learning modules related to innovation processes, identifying where good ideas come from, working in teams, leadership, project management, and communication and presentation skills; 2) team innovation projects, one topic-assigned, applying skills learned in the content modules to develop innovation and team collaboration skills; and 3) integration of business students with STEM students which together gives viewpoints and experiences on product and customer needs. It is important to our nation’s health and safety to instill innovation in our students. In addition, today’s students are interested in innovation and in learning how to apply innovation techniques in their professional and personal lives. The course was designed for teams of four STEM students to one business student which provides a balanced input needed for this type of project taking into account the skillset of the technically oriented STEM students and the marketing-oriented business students, as well as personality types. This ensures that all voices are heard, and topical areas are addressed. There was no problem in getting faculty interest in developing the course, and the collaboration between retention professionals and faculty went well. After the course, an iterative improvement retrospective will be performed on the program as implemented to this point to inform improvements for next year’s cohort. This material is based upon work supported by the National Science Foundation under Grant No. 2030297. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the National Science Foundation.« less