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1. Strategies for Developing, Expanding, and Strengthening Community College Engineering Transfer Programs

   Enriquez, A.; Langhoff, N.; Dunmire, E.; Rebold, T; Pong, W. (June 2018, American Society for Engineering Education)

   Broadening participation in engineering among underrepresented minority students remains a big challenge for institutions of higher education. Since a large majority of underrepresented students attend community colleges, engineering transfer programs at these community colleges can play an important role in addressing this challenge. However, for most community college engineering programs, developing strategies and programs to increase the number and diversity of students successfully pursuing careers in engineering is especially challenging due to limited expertise, shrinking resources, and continuing budget crises. This paper is a description of how a small engineering transfer program at a Hispanic-Serving community college in California developed effective partnerships with high schools, other institutions of higher education, and industry partners in order to create opportunities for underrepresented community college students to excel in engineering. Developed through these partnerships are programs for high school students, current community college students, and community college engineering faculty. Programs for high school students include a) the Summer Engineering Institute – a two-week residential summer camp for sophomore and junior high school students, and b) the STEM Institute – a three-week program for high school freshmen to explore STEM fields. Academic and support programs for college students include: a) Math Jam – a one-week intensive math placement test review and preparation program; b) a scholarship and mentoring program academically talented and financially needy STEM students; c) a two-week introduction to research program held during the winter break to prepare students for research internships; d) a ten-week summer research internship program; e) Physics Jam – an intensive program to prepare students for success in Physics; f) Embedded Peer Instruction Cohort – a modified Supplemental Instruction program for STEM courses; g) STEM Speaker Series – a weekly presentation by professionals talking about their career and educational paths. Programs for community college STEM faculty and transfer programs include: a) Summer Engineering Teaching Institute – a two-day teaching workshop for community college STEM faculty; b) Joint Engineering Program – a consortium of 28 community college engineering programs all over California to align curriculum, improve teaching effectiveness, improve the engineering transfer process, and strengthen community college engineering transfer programs; c) Creating Alternative Learning Strategies for Transfer Engineering Programs – a collaborative program that aims to increase access to engineering courses for community college students through online instruction and alternative classroom models; and d) California Lower-Division Engineering Articulation Workshop – to align the engineering curriculum. In addition to describing the development and implementation of these programs, the paper will also provide details on how they have contributed to increasing the interest, facilitating the entry, improving the retention and enhancing the success of underrepresented minority students in engineering, as well as contributing to the strengthening of the community college engineering education pipeline. 

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2. Pre-College Summer Program in Entrepreneurial and Design Thinking Influences STEM Success for African American Students

   https://doi.org/10.15695/jstem/v7i2.03  

   Jackson, Caesar R; Whittington, Dawayne; Bradley, Tanina (February 2024, The Journal of STEM Outreach)

   Shepherd, Virginia L; Chester, Ann; Bass, Kristin M (Ed.)

   Sustained innovation and economic strength of the U.S depends on a greater participation of underrepresented minorities in science, technology, engineering, and mathematics (STEM). University-based outreach programs that serve African American and other minority populations should do more to infuse invention education in activities that engage pre-college students from these groups to motivate them to pursue STEM degrees. The Research, Discovery, and Innovation (RDI) Summer Institute is a design and science entrepreneurship program that is offered at North Carolina Central University to high school seniors who have been accepted for admission to a STEM degree program at the university. This study found the RDI Summer Institute program to be effective based on proximal outcomes of gains in composite entrepreneurial thinking skills (entrepreneurial, managerial, engineering design, and technical skills) as perceived by the participants and measured by pre- and post-surveys. Eighty-seven percent of the pre-college participants were African Americans, showed high levels of creativity and innovativeness, and presented product ideas that were conscientious in meeting their community needs. Program impact was assessed based on near-term and distal academic outcomes in college through a rigorously designed quasi-experiment which compared 31 case-control matched pairs of students who had been RDI participants and non-RDI participants. A conditional logistic regression showed first-year retention in STEM degree programs for students who had been RDI participants was five times that of students who had been non-RDI participants. Additionally, first-year STEM retention in differential comparisons favored female students, students from very low/low SES households, and students from single parent households. Also, students who had been RDI participants performed higher in STEM gatekeeper courses, and a strong positive impact of the RDI Summer Institute program was associated with higher STEM persistence even two and three years after pre-college students participated. 

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3. Non-Academic Careers for STS Graduate Students: Hopping off the Tenure Track

   https://doi.org/10.1007/s11024-018-9360-6  

   Woodson, Thomas S.; Harsh, Matthew; Foley, Rider (January 2018, Minerva)

   Science, Technology & Society (STS) graduate programs primarily train graduate students to work in tenure track academic jobs. However, there are not enough tenure track academic jobs to match the supply of STS graduate students, nor does every STS graduate student want to become an academic. As a start to addressing these challenges, we hosted workshops before the 2017 Society for the Annual Meeting of the Society Studies of Science and the 2018 ST Global conference. In those workshops, panelists with PhDs in STS and related fields and working in non-academic faculty careers such as government agencies, non-profit foundations, and industry emphasized that students must showcase how their skills are useful to non-academic organizations. The panelists offered a wealth of stories on how their STS perspective supported their careers, yet most had faced implicit and explicit mentoring from STS faculty that ran counter to their career aspirations. The conversations centered on reframing research and conveying to potential employers how their STS training would support their future careers. A takeaway point that resonated with many participants was the need for STS graduate programs to rethink how they market themselves, recruit students, and critically reflect upon the measures of success. By implicitly steering graduate students solely towards an academic career, STS graduate training will miss an opportunity to make a positive impact on society 

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4. Implementing Integrated Project-Based Learning Outcomes in a 21st-Century Environmental Engineering Curriculum

   Gallagher, S.; Phillips, A.; Lauchnor, E.; Hohner, A.; Stein, O. R.; Woolard, C. R.; Kirkland, C. M.; Plymesser, K (June 2022, 2023 ASEE annual conference exposition)

   Engineering education research and accreditation criteria have for some time emphasized that to adequately prepare engineers to meet 21st century challenges, programs need to move toward an approach that integrates professional knowledge, skills, and real-world experiences throughout the curriculum [1], [2], [3]. An integrated approach allows students to draw connections between different disciplinary content, develop professional skills through practice, and relate their emerging engineering competencies to the problems and communities they care about [4], [5]. Despite the known benefits, the challenges to implementing such major programmatic changes are myriad, including faculty’s limited expertise outside their own disciplinary area of specialization and lack of perspective of professional learning outcomes across the curriculum. In 2020, Montana State University initiated a five-year NSF-funded Revolutionizing Engineering Departments (RED) project to transform its environmental engineering program by replacing traditional topic-focused courses with a newly developed integrated and project-based curriculum (IPBC). The project engages all tenure-track faculty in the environmental engineering program as well as faculty from five external departments in a collaborative, iterative process to define what students should be expected to know and do at the completion of the undergraduate program. In the process, sustainability, professionalism, and systems thinking arose as foundational pillars of the successful environmental engineer and are proposed as three knowledge threads that can be woven throughout environmental engineering curricula. The paper explores the two-year programmatic redesign process and examines how lessons learned through the process can be applied to course development as the team transitions into the implementation phase of the project. Two new integrated project-based learning courses targeting the 1st- and 2nd-year levels will be taught in academic year 2023-2024. The approach described in this work can be utilized by similar programs as a model for bottom-up curriculum development and integration of non-technical content, which will be necessary for educating engineers of the future. 

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5. A workshop for and by disciplinary STEM faculty: Learn how to design high-quality qualitative educational research!

   Morelock, John R.; Jarvie-Eggart, Michelle; Chenette, Heather; Hooshangi, Sara; Chesnutt, Betsy; Wilson, Sarah; Bolhari, Azadeh; Dodson, Kirsten; Pavlova, Iglika; Reck, Rebecca (December 2023, Proceedings Frontiers in Education Conference)

   The purpose of this workshop is to introduce instructional and disciplinary tenure-track STEM faculty to high-quality qualitative research design in order to explore their intellectual curiosity around STEM education. We will do so using the ProQual approach, a methodologically unencumbered and widely accessible way of thinking about qualitative research design that was deployed and refined over the last three years as part of the NSF-funded ProQual Institute for Research Methods. This workshop will be conducted by STEM faculty who have graduated from the ProQual Institute, who are culturally sensitive to the challenges faced by disciplinary STEM faculty. Leveraging a propagation model of effecting academic change, these workshop leaders will also serve as a community of practice to help workshop participants move their educational research ideas forward during and after the workshop. 

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