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1. Initial Observations of a Community College Microsystem Fabrication-focused Undergraduate Research Experience

   https://doi.org/10.5281/zenodo.6494275  

   Rocio Vazquez, Irma; Sharma, Pallavi; Law, Victor; Jackson, Nathan; Pleil, Matthias (January 2022, Journal of advanced technological education)

   Providing hands-on learning experiences increases student understanding of theory and practices in STEM (science, technology, engineering, and mathematics) fields. The experience gives students motivation and allows them to focus their career path towards completing a degree in a STEM field. This paper provides initial observations on the learning impact of community college students and their instructors participating in the Support Center for Microsystems Education 2021 Undergraduate Research Experience. Twenty undergraduate community college students and their instructors participated in a week-long hands-on project-based course in a cleanroom environment. Both students and instructors showed an increase in the level of knowledge regarding microfabricating based on the collected survey results after completing the program. Survey results and observations of participating mentors are presented. 

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2. HSI Implementation and Evaluation Project: THE FRESHMAN YEAR INNOVATOR EXPERIENCE (FYIE): BRIDGING THE URM GAP in STEM

   Vargas_Hernandez, Noe; Ortega, Javier; Lozano, Karen; Marquez, Eleazar; Fuentes, Arturo (June 2024, 2024 ASEE Conference)

   The Freshman Year Innovator Experience (FYIE) program at The University of Texas Rio Grande Valley, a Minority Serving Institution (MSI), aims to enhance the freshman experience for incoming students by developing key academic success skills. The program is developing self-transformation skills in freshman mechanical engineering students to help them overcome academic and professional challenges exacerbated by the COVID-19 pandemic. FYIE participants are taking two courses simultaneously: Introduction to Engineering (Course A) and Learning Frameworks (Course B). In Course A, students will complete a 6-week engineering design project, and in Course B, they are completing a 6-week academic career path project. During these parallel projects, timed interventions demonstrate the analogies between the engineering design process and the academic career pathways project. The objective is for students to realize that they can apply the design thinking skills they learn in the engineering design process to solve their academic career challenges. A pilot of the FYIE program began in the 2023 Spring semester, with instructors from Course A and B introducing the parallel projects. The pilot continues in the 2023 Fall semester, with refinements to the parallel projects and the definition of analogy intervention points for self-transformation. The authors of the paper will present the results from the pilot implementations, as well as discuss the challenges and future work. This proposed initiative is designed with the intention of adhering to the ongoing mission of the College of Engineering and Computer Science (CECS) at the UTRGV to 1) increase the number of STEM degrees awarded to Hispanics, 2) broadening participation of females in STEM related fields, and 3) increase the persistence and self-efficacy in STEM fields amid COVID-19. This project is funded by NSF award 2225247. 

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3. A Longitudinal Study to Investigate the Impact of a Service-Learning Course on Its Participants

   Xu, Xin; Jin, Wei; Barakat, Rahaf; Dekhane, Sonal; Gunay, Cengiz; Doloc-Mihu, Anca; Robertson, Cindy (July 2024, American Council on Science & Education (CSCE 2024))

   The Technology Ambassador’s Program (TAP) was established in 2012 as an extra-curricular program and has been offered as a service learning course since spring 2016. To investigate the impact on program participants, we launched a longitudinal study in fall 2022 and surveyed the students who completed the course from spring 2016 to spring 2021. Analysis of the survey results discovered that students strongly agree that this program has provided them opportunities to conduct research, to network with other professionals in the field, and apply technical skills. Further analysis also revealed a strong correlation of these opportunities with improving soft skills and career readiness among participants. Overall, this program increased the confidence of the students and prepared them to learn new skills on their own. This paper describes the overall structure of the service learning program and presents the details of this study including the process and survey results. 

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4. Board 245: Description, Assessment, and Outcomes of Several Interventions within a National Science Foundation Research Traineeship (NRT): Graduate Certificate, Field Trips, Internships and International Experiences

   https://doi.org/10.18260/1-2--42688  

   Santillan-Jimenez, Eduardo; Schutzman, Carissa; Mabisi, Keren; Biswas, Apala (June 2023, ASEE Conferences)

   An ongoing National Science Foundation Research Traineeship (NRT) aims to enhance graduate education by integrating research and professional skill development within a diverse, inclusive, and supportive academy. This contribution will describe several interventions within this NRT, namely, a graduate certificate on Innovations at the Nexus of Food, Energy, and Water Systems (INFEWS) – which is the research topic of the NRT – field trips to sites related to INFEWS, internships and international experiences. Moreover, the assessment and outcomes of each of these interventions will be discussed. A graduate certificate on INFEWS established through this NRT aims to 1) impart both conceptual and technical knowledge related to INFEWS to students; 2) provide them with training on key transferable skills; and 3) equip them to consider the societal, cultural, behavioral, and economic aspects of research on the food, energy, and water nexus. The starting point of the certificate is a multi-departmental and interdisciplinary course on INFEWS. In a subsequent semester students receive training on key transferrable skills in a course designed to integrate these skills with content covered in the foregoing INFEWS course. Completing these core courses gives students 6 of the 12 credit hours needed to attain the certificate. Students earn the other 6 credits by choosing from a list of elective courses. Notably, courses fulfill both certificate and degree requirements, so anticipated time-to-degree is not extended. The certificate is evaluated by assessing student learning outcomes with multiple measures, which include teacher course evaluations of individual courses, the rubric used to review a research proposal that students prepare in the transferable skills course, a professional skills dossier, competency assessments, and student post-surveys. While field trips to facilities related to INFEWS and internships at sites best aligned with their career interests – inside or outside academia – helped foster a sense of community among trainees and exposed them to various work sites and career paths, international experiences helped them gain a global perspective and appreciation for the international nature of STEM research. Evaluation data related to field trips, internships, and international experiences are collected via student focus group discussions, student post-surveys, student follow-up surveys, and alumni surveys. Additionally, the number and type of internships are tracked, and student placement with the internship host after graduation is also monitored. By sharing a description of these interventions and details about their evaluation as well as their outcomes, this contribution will inform practitioners interested in similar educational programs and experiences of both challenges and opportunities associated with these initiatives. In turn, this will help the higher education community in its pursuit to identify and implement the best and most effective practices. 

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5. Work in Progress: Teaching Engineering Students to Self-Transform: Parallelisms between Product Innovation and Student Career Path Planning

   Vargas_Hernandez, Noe; Ortega, Javier; Lozano, Karen; Fuentes, Arturo; Marquez, Eleazar (June 2024, ASEE Conference)

   Freshman engineering students can have a hard time transitioning to college. The freshman year is critical to the students’ academic success; in this year they learn basic skills and establish essential networks with other students, faculty, and resources. How can we help these freshman engineering students in this transition? We propose that freshman students can learn from the engineering design innovation process and apply it by analogy to the design of their academic pathways. There are multiple similarities between product innovation (i.e., technology) and the continuous academic challenges faced by the student. Engineers as designers and innovators have a vast and rich repository of techniques, tools, and approaches to develop new technologies, and a parallelism can be drawn between the design and innovation of a technology (e.g., redesign of a kitchen appliance), and the “design” of the students’ academic career pathways. During the Spring 2023 semester pilot, students in Intro to Mechanical Engineering (Course A) worked in teams in a 6-week product innovation project to redesign a simple kitchen appliance. Students learned basic concepts of the design process (e.g., creative exploration of solutions, decision making, multi objective evaluation, etc.). These same students concurrently took Course B (Learning Frameworks) where they worked on a 6-week project to define their career pathways. Both projects, product innovation and career pathways, followed the Challenge Based Instruction (CBI) approach. Periodically, participant students were shown how to use the lessons from product innovation by analogy and reflection in their career pathways project. The objective is for students to learn about the engineering design process and to apply it to their academic challenges by analogy. This prepares students with meta skills to help solve future problems in their academic path, and at each iteration, the students transform themselves, hence the use of the term self-transformation (also referred as “self-innovation”). Data collected from pre and post surveys will be presented to measure self-efficacy in engineering design, grit, motivation to learn, and STEM identity. Participant interviews provide a qualitative insight into the intervention. This project is funded by NSF award 2225247. 

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