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1. Communities Support Engineering as a College Major Choice

   https://doi.org/10.18260/1-2--34307  

   Vaziri, S.L.; Paretti, M.C.; Grohs, J.R.; Baum, L.M.; Lester, M.M.; Newbill, P.L. (July 2020, Zone 1 Conference of the American Society for Engineering Education)

   Broadening participation in engineering is critical given the gap between the nation’s need for engineering graduates and its production of them. Efforts to spark interest in engineering among PreK-12 students have increased substantially in recent years as a result. However, past research has demonstrated that interest is not always sufficient to help students pursue engineering majors, particularly for rural students. In many rural communities, influential adults (family, friends, teachers) are often the primary influence on career choice, while factors such as community values, lack of social and cultural capital, limited course availability, and inadequate financial resources act as potential barriers. To account for these contextual factors, this project shifts the focus from individual students to the communities to understand how key stakeholders and organizations support engineering as a major choice and addresses the following questions: RQ1. What do current undergraduate engineering students who graduated from rural high schools describe as influences on their choice to attend college and pursue engineering as a post-secondary major? RQ2. How does the college choice process differ for rural students who enrolled in a 4-year university immediately after graduating from high school and those who transferred from a 2-year institution? RQ3. How do community members describe the resources that serve as key supports as well as the barriers that hinder support in their community? RQ4. What strategies do community members perceive their community should implement to enhance their ability to support engineering as a potential career choice? RQ5. How are these supports transferable or adaptable by other schools? What community-level factors support or inhibit transfer and adaptation? To answer the research questions, we employed a three-phase qualitative study. Phase 1 focused on understanding the experiences and perceptions of current [University Name] students from higher-producing rural schools. Analysis of focus group and interview data with 52 students highlighted the importance of interest and support from influential adults in students’ decision to major in engineering. One key finding from this phase was the importance of community college for many of our participants. Transfer students who attended community college before enrolling at [University Name] discussed the financial influences on their decision and the benefits of higher education much more frequently than their peers. In Phase 2, we used the findings from Phase 1 to conduct interviews within the participants’ home communities. This phase helped triangulate students’ perceptions with the perceptions and practices of others, and, equally importantly, allowed us to understand the goals, attitudes, and experiences of school personnel and local community members as they work with students. Participants from the students’ home communities indicated that there were few opportunities for students to learn more about engineering careers and provided suggestions for how colleges and universities could be more involved with students from their community. Phase 3, scheduled for Spring 2020, will bring the findings from Phases 1 and 2 back to rural communities via two participatory design workshops. These workshops, designed to share our findings and foster collaborative dialogue among the participants, will enable us to explore factors that support or hinder transfer of findings and to identify policies and strategies that would enhance each community’s ability to support engineering as a potential career choice. 

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2. Exploring the career thinking of Native American engineering students

   Colston, Nicole; Turner, Sherri L.; Johnson, Sarah; Jacobs, Sue C.; Mason-Chagil, Gale (June 2019, American Society for Engineering Education (2019); Paper #26791)

   Recent reports indicate that there are less than 1900 (0.6%) Native American undergraduate and graduate engineering students nationwide (Yoder, 2016). Although Native Americans are underrepresented in the field of engineering, there is very little research that explores the contributing factors. The purpose of our exploratory research is to identify the barriers, supports, and personal strengths that Native American engineering students identify as being influential in developing their career interests and aspirations in engineering. Informed by research in Social Cognitive Career Theory (SCCT; Lent, Brown, & Hackett, 1994, 2000), we conducted an online survey to assess the motivational variables that guide the career thinking and advancement of students preparing to enter the field of engineering. Instrumentation included Mapping Vocational Challenges (Lapan & Turner, 2000, 2009, 2014), Perceptions of Barriers (McWhirter, 1997), the Structured Career Development Inventory (Lapan & Turner, 2006; Turner et al., 2006), the Career-Related Parent Support Scale (Turner, Alliman-Brissett, Lapan, Udipi, & Ergun, 2003), and the Assessment of Campus Climate for Underrepresented Groups (Rankin, 2001), which were used to measure interests, goals, personal strengths and internal and external barriers and supports. Participants (N=23) consisted of graduate (≈25%) and undergraduate (≈75%) Native American engineering students. Their survey responses indicated that students were highly interested in, and had strong self-efficacy for, outcome expectations for, and persistence for pursuing their engineering careers. Their most challenging barriers were financial (e.g., having expenses that are greater than income, and having to work while going to school just to make ends meet) and academic barriers (e.g., not sufficiently prepared academically to study engineering). Perceptions of not fitting in and a lack of career information were also identified as moderately challenging barriers. Students endorsed a number of personal strengths, with the strongest being confidence in their own communication and collaboration skills, as well as commitment to their academic and career preparation. The most notable external support to their engineering career development was their parents’ encouragement to make good grades and to go to a school where they could prepare for a STEM career. Students overall found that their engineering program climates (i.e., interactions with students, faculty, staff, and program expectations of how individuals treat each other) were cooperative, friendly, equitable, and respectful. Study results are interpreted in light of SCCT and recommendations for future research and practice in engineering education are provided. 

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3. Development and Assessment of a Combined REU/RET Program in Materials Science

   Salzman, N.; Ubic, R. (April 2017, ASEE Annual Conference proceedings)

   In this paper we present an evaluation and lessons learned from a joint Research Experience for Undergraduates (REU) and Research Experience for Teachers (RET) program focused on energy and sustainability topics within a Materials Science and Engineering program at a public university. This program brought eleven undergraduate science and engineering students with diverse educational and institutional backgrounds and four local middle and high school teachers on campus for an 8-week research experience working in established lab groups at the university. Using the Qualtrics online survey software, we conducted pre-experience and post-experience surveys of the participants to assess the effects of participating in this summer research program. At the beginning of the summer, all participants provided their definition of technical research and described what they hoped to get out of their research experience, and the undergraduate students described their future career and educational plans. At the conclusion of the summer, a post-experience survey presented participants’ with their answers from the beginning of the summer and asked them to reflect on how their understanding of research and future plans involving research changed over the course of the summer experience. Many participants evolved a new understanding of research as a result of participating in the summer experience. In particular, they better recognized the collaborative nature of research and the challenges that can arise as part of the process of doing research. Participants acquired both technical and professional skills that they found useful, such as learning new programming languages, becoming proficient at using new pieces of equipment, reviewing technical literature, and improving presentation and communication skills. Undergraduates benefited from developing new relationships with their peers, while the teacher participants benefited from developing relationships with faculty and staff at the university. While most of the participants felt that they were better prepared for future studies or employment, they did not feel like the summer research experience had a significant impact on their future career or degree plans. Finally, while almost all of the participants described their summer research experience as positive, areas for improvement included better planning and access to mentors, as well as more structured activities for the teachers to adapt their research activities for the classroom. 

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4. Community Cultures: Broadening Participation By Understanding How Rural Communities Support Engineering as a College Major Choice

   Paretti, Marie C.; Grohs, Jacob R.; Anderson, William Michael; Lester, Marlena McGlothlin; Baum, Liesl M.; Newbill, Phyllis Leary; Kelly, Stacey Leigh (July 2018, 2018 ASEE Annual Conference & Exposition)

   his project is supported by an NSF BPE grant. Career choices, such as engineering, are influenced by a number of factors including personal interest, ability, competence beliefs, prior work-related experience, and financial and social supports. However, financial and social support, a particularly significant factor for rural students’ career decisions, is often overlooked in the literature exploring career choice. Moreover, little work has explored how communities serve as key influencers for supporting or promoting engineering as a career choice. Therefore, the goal of this study is to explore the ways in which communities provide support to students deciding to pursue engineering as a college major. To better understand how students from selected rural area high schools choose engineering as a major, we conducted focus group discussions consisting of 4-6 students each from selected schools to talk collectively about their high school experiences and their choice to major in engineering. Choosing focus group participants from different schools enabled us to elicit tacit perceptions and beliefs that may not be evident when students from the same community talk with one another. That is, as students share their experiences across schools, they may recognize differences in their experiences that, though otherwise unconscious or unacknowledged, proved significant in their choice of college and major. We expect that certain community programs and the individuals involved will have some influence on students’ decisions to study engineering at [University Name]. We anticipate that the results will yield two key outcomes: 1. A holistic understanding of the communities that effectively support and encourage engineering major choice for rural students. 2. Locally driven, contextually relevant recommendations for policies and programs that would better enable economically disadvantaged, rural schools in southwestern Virginia to support engineering as a career choice for high school students. By understanding the ways some economically-disadvantaged rural communities support engineering as a career choice and linking a broad spectrum of rural communities together around this issue, this project will broaden participation in engineering by increasing support for students from these areas. By shifting our focus from students to communities, this research broadens our understanding of career choice by capturing the perspectives of community members (including not only school personnel, but also community leaders, students’ families, business owners and others) who often play a key role in students’ decisions, particularly in rural communities. Our research will bring these voices into the conversation to help scholars learn from and respond to these essential community perspectives. In doing so, we will provide a more nuanced model of engineering career choice that can then be explored in other rural contexts. This work thus contributes to the research on career choice, rural education, and engineering education. © 2018 American Society for Engineering Education 

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5. Financial and Interdisciplinary Support Programs Differentially Support Low Income Scholars Through COVID

   Kling, Thomas; King, Colby; Solomon, Jibril; Waratuke, Stephen; Aizenman, Jennifer (November 2022, Transforming STEM Higher Education)

   Students Engaging In Scientific and Mathematical Interdisciplinary Collaboration (NSF 164375), supports low-income, academically talented Scholars with multiple components including scholarships, paid undergraduate research, service learning, social science and humanities courses, and career development. Scholars will graduate in STEM at a rate of 95%, higher than the rate of eligible, non-participants (62%). High percentages of Scholars attribute increased understanding of the interdisciplinary nature of STEM and growth in on-campus support networks to programming. However, they report variation in the components to which they attribute those gains, with most participants acknowledging the importance of engagement with different program components over time. Scholars report differences in off-campus work, which may have been impacted by the Covid pandemic. While all Scholars starting at the onset of the Covid pandemic were retained in STEM, retention of eligible, non-participants fell from 70% to 38%, indicating the importance of financial and communal support during challenging times. 

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