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1. We Are Thriving: Increasing the Number of Women in Engineering

   https://doi.org/strategy.asee.org/41518  

   Redmond, K. ; Panther, G ; Asadollahipajouh, M. ; Evans, R. ; Kulesza, S. ; Liang, G. ( August 2022 , 2022 ASEE Annual Conference & Exposition)

   An ongoing focus of engineering education research is on increasing the number of women in engineering. Previous studies have primarily focused on examining why the number of women enrolled in engineering colleges remains persistently low. In doing so, while we have gained better understanding of the challenges and barriers that women encountered and factors that contribute to such negative experiences, it also, as some scholars have pointed out, has cast a deficit frame on such matters. In this study, we take on a positive stand where we focus on women undergraduate students who not only “stay” but also succeed in engineering programs (that is, our definition of thriving) as a way to locate the personal and institutional factors that facilitate such positive outcomes. Our initial pilot study involved two female engineering undergraduate students at an R1 university. Each student was interviewed three times. While each of the interviews in the sequence had a slightly different focus, the overall goal was to understand the women’s autobiographic and educational experiences leading to their paths to engineering and participation in the engineering project teams. The inductive thematic analysis revealed several primary findings which subsequently played a major role in developing a codebook for the current study. Building upon what is learned from the pilot study, the current study uses a layered multi-case study design involving three institutions: a public/private Ivy League and statutory land-grand research university in the Northeast, a public land-grant research university in the Midwest, and a public land-grant research university in the Southwest which is also designated as MSI/HSI. In addition to the interview method, data collection also contains documents and artifacts. For this paper, we zone in onto the data collected in the first interviews, known as the “life history” where we mainly learn about the women undergraduate participants’ personal-familial contexts that contribute to their entry to majoring in engineering as identified by the women themselves. Preliminary findings indicate that: (1) our participants tend to have supportive families; (2) while all experienced gender biases, not everyone has formed a critical consciousness of sexism; and (3) being able to actually engage by “doing” something and creating a product is key to the women’s finding joy in engineering and associating themself with the field/profession. It is important to note that the second interviews, which focus on the educational journey of the participants in relation to engineering identity development and project team experiences, are underway. The ultimate goal for the study is to develop a theoretical framework speaking to a multifaceted model of forces (micro as autobiographic, macro as institutional, and in-between or middle-level as team-based) in shaping women’s entry and advance in engineering programs. This framework will recognize the variations in institutional type, resource availability, and structural and cultural characteristics and traditions in teams. It will also use such differences to show possibilities of more versatile ways for diversifying pathways for women and other minoritized groups to thrive in engineering. 

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2. Effects of High Impact Educational Practices on engineering and computer science student participation, persistence, and success at land grant universities: YEAR 2.

   Asghar, M. ( August 2022 , 2022 ASEE Annual Conference & Exposition)

   Effects of High Impact Educational Practices on Engineering and Computer Science Student Participation, Persistence, and Success at Land Grant Universities: Award# RIEF-1927218 – Year 2 Abstract Funded by the National Science Foundation (NSF), this project aims to investigate and identify associations (if any) that exist between student participation in High Impact Educational Practices (HIP) and their educational outcomes in undergraduate engineering and computer science (E/CS) programs. To understand the effects of HIP participation among E/CS students from groups historically underrepresented and underserved in E/CS, this study takes place within the rural, public university context at two western land grant institutions (one of which is an Hispanic-serving institution). Conceptualizing diversity broadly, this study considers gender, race and ethnicity, and first-generation, transfer, and nontraditional student status to be facets of identity that contribute to the diversity of academic programs and the technical workforce. This sequential, explanatory, mixed-methods study is guided by the following research questions: 1. To what extent do E/CS students participate in HIP? 2. What relationships (if any) exist between E/CS student participation in HIP and their educational outcomes (i.e., persistence in major, academic performance, and graduation)? 3. How do contextual factors (e.g., institutional, programmatic, personal, social, financial, etc.) affect E/CS student awareness of, interest in, and participation in HIP? During Project Year 1, a survey driven quantitative study was conducted. A survey informed by results of the National Survey of Student Engagement (NSSE) from each institution was developed and deployed. Survey respondents (N = 531) were students enrolled in undergraduate E/CS programs at either institution. Frequency distribution analyses were conducted to assess the respondents’ level of participation in extracurricular HIPs (i.e., global learning and study aboard, internships, learning communities, service and community-based learning, and undergraduate research) that have been shown in the literature to positively impact undergraduate student success. Further statistical analysis was conducted to understand the effects of HIP participation, coursework enjoyability, and confidence at completing a degree on the academic success of underrepresented and nontraditional E/CS students. Exploratory factor analysis was used to derive an "academic success" variable from five items that sought to measure how students persevere to attain academic goals. Results showed that a linear relationship in the target population exists and that the resultant multiple regression model is a good fit for the data. During the Project Year 2, survey results were used to develop focus group interview protocols and guide the purposive selection of focus group participants. Focus group interviews were conducted with a total of 27 undergraduates (12 males, 15 females, 16 engineering students, 11 computer science students) across both institutions via video conferencing (i.e., ZOOM) during the spring and fall 2021 semesters. Currently, verified focus group transcripts are being systematically analyzed and coded by a team of four trained coders to identify themes and answer the research questions. This paper will provide an overview of the preliminary themes so far identified. Future project activities during Project Year 3 will focus on refining themes identified during the focus group transcript analysis. Survey and focus group data will then be combined to develop deeper understandings of why and how E/CS students participate in the HIP at their university, taking into account the institutional and programmatic contexts at each institution. Ultimately, the project will develop and disseminate recommendations for improving diverse E/CS student awareness of, interest in, and participation in HIP, at similar land grant institutions nationally. 

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3. Lived Experiences of African American Engineering Students at a PWI Through the Lens of Navigational Capital

   Damas, S. ; Benson, L. ( February 2022 , 2022 CoNECD (Collaborative Network for Engineering & Computing Diversity))

   There are significant disparities between the conferring of science, technology, engineering, and mathematics (STEM) bachelor’s degrees to minoritized groups and the number of STEM faculty that represent minoritized groups at four-year predominantly White institutions (PWIs). Studies show that as of 2019, African American faculty at PWIs have increased by only 2.3% in the last 20 years. This study explores the ways in which this imbalance affects minoritized students in engineering majors. Our research objective is to describe the ways in which African American students navigate their way to success in an engineering program at a PWI where the minoritized faculty representation is less than 10%. In this study, we define success as completion of an undergraduate degree and matriculation into a Ph.D. program. Research shows that African American students struggle with feeling like the “outsider within” in graduate programs and that the engineering culture can permeate from undergraduate to graduate programs. We address our research objective by conducting interviews using navigational capital as our theoretical framework, which can be defined as resilience, academic invulnerability, and skills. These three concepts come together to denote the journey of an individual as they achieve success in an environment not created with them in mind. Navigational capital has been applied in education contexts to study minoritized groups, and specifically in engineering education to study the persistence of students of color. Research on navigational capital often focuses on how participants acquire resources from others. There is a limited focus on the experience of the student as the individual agent exercising their own navigational capital. Drawing from and adapting the framework of navigational capital, this study provides rich descriptions of the lived experiences of African American students in an engineering program at a PWI as they navigated their way to academic success in a system that was not designed with them in mind. This pilot study took place at a research-intensive, land grant PWI in the southeastern United States. We recruited two students who identify as African American and are in the first year of their Ph.D. program in an engineering major. Our interview protocol was adapted from a related study about student motivation, identity, and sense of belonging in engineering. After transcribing interviews with these participants, we began our qualitative analysis with a priori coding, drawing from the framework of navigational capital, to identify the experiences, connections, involvement, and resources the participants tapped into as they maneuvered their way to success in an undergraduate engineering program at a PWI. To identify other aspects of the participants’ experiences that were not reflected in that framework, we also used open coding. The results showed that the participants tapped into their navigational capital when they used experiences, connections, involvement, and resources to be resilient, academically invulnerable, and skillful. They learned from experiences (theirs or others’), capitalized on their connections, positioned themselves through involvement, and used their resources to achieve success in their engineering program. The participants identified their experiences, connections, and involvement. For example, one participant who came from a blended family (African American and White) drew from the experiences she had with her blended family. Her experiences helped her to understand the cultures of Black and White people. She was able to turn that into a skill to connect with others at her PWI. The point at which she took her familial experiences to use as a skill to maneuver her way to success at a PWI was an example of her navigational capital. Another participant capitalized on his connections to develop academic invulnerability. He was able to build his connections by making meaningful relationships with his classmates. He knew the importance of having reliable people to be there for him when he encountered a topic he did not understand. He cultivated an environment through relationships with classmates that set him up to achieve academic invulnerability in his classes. The participants spoke least about how they used their resources. The few mentions of resources were not distinct enough to make any substantial connection to the factors that denote navigational capital. The participants spoke explicitly about the PWI culture in their engineering department. From open coding, we identified the theme that participants did not expect to have role models in their major that looked like them and went into their undergraduate experience with the understanding that they will be the distinct minority in their classes. They did not make notable mention of how a lack of minority faculty affected their success. Upon acceptance, they took on the challenge of being a racial minority in exchange for a well-recognized degree they felt would have more value compared to engineering programs at other universities. They identified ways they maneuvered around their expectation that they would not have representative role models through their use of navigational capital. Integrating knowledge from the framework of navigational capital and its existing applications in engineering and education allows us the opportunity to learn from African American students that have succeeded in engineering programs with low minority faculty representation. The future directions of this work are to outline strategies that could enhance the path of minoritized engineering students towards success and to lay a foundation for understanding the use of navigational capital by minoritized students in engineering at PWIs. Students at PWIs can benefit from understanding their own navigational capital to help them identify ways to successfully navigate educational institutions. Students’ awareness of their capacity to maintain high levels of achievement, their connections to networks that facilitate navigation, and their ability to draw from experiences to enhance resilience provide them with the agency to unleash the invisible factors of their potential to be innovators in their collegiate and work environments. 

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4. Board 314: Implementing the Vertically Integrated Projects (VIP) Model at a Public Urban Research University in the Southeastern United States

   Preza, Chrysanthe ; Ivey, Stephanie S. ; Stewart, Craig O. ( June 2023 , ASEE annual conference exposition)

   Underproduction, low retention, and lack of diversity in STEM disciplines, especially engineering, are significant challenges nationally, but are particularly acute in regions, both urban and rural, where educational access is limited. Leveraging our institutional location at a public urban research university in a city marked by its connection to its rural surroundings, we seek to address these challenges by implementing the Vertically Integrated Projects (VIP) model at our university with the support of an NSF IUSE grant. The VIP model is based on active learning and enables tiered mentoring from students at all academic years, thereby providing the opportunity of role modeling from upper-level undergraduate and graduate students as well as faculty. In addition, programs based on the VIP model are accessible to all students (not just high performing students) and provide a meaningful networking environment. We use our implementation of the VIP model to foster STEM identity growth and a sense of belonging, while increasing and celebrating diversity in engineering and other STEM disciplines. Our VIP program leverages best practices from the well-established VIP model and adapts it to address unique aspects of our university’s community and interests. Specifically, the program includes freshmen and will also serve as a recruitment tool for local community college students. It employs a tiered mentoring approach and activities that prepare students for research and foster networking. The long-term goal of the VIP experience is to create a research culture and community in engineering and eventually across STEM disciplines that is inclusive and supportive of students from diverse backgrounds. An additional focus is to showcase the value of diversity in research and innovation through the program. Both the research culture and increased acknowledgement of the value of diversity are designed to enhance students’ STEM identity, which is important for retention in the major and career. The purpose of this paper is to report on the planning and launch of our VIP program in Fall 2022, focusing on the PIs’ experiences implementing the program and on our first cohort’s (N = 12; 7 women; 4 Black/African American; 2 Hispanic) experiences participating in the program during their first semester. Specifically, this paper will describe the challenges and opportunities of implementing the VIP program and how the VIP model has been adapted to align with unique aspects of our institution and student body. We will also report preliminary analyses of student journal data collected from the first cohort throughout the Fall semester, where students described their initial expectations/hopes and concerns for the semester; their activities and emotional responses during the semester; and finally, their reflections on their experiences, positive or negative, throughout the semester. The paper will conclude by offering lessons learned from the first year of this project as well as directions for moving forward. 

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5. Effects of High Impact Educational Practices on Engineering and Computer Science Student Participation, Persistence, and Success at Land Grant Universities

   Claiborn, Candis ; Minichiello, Angela ; Adesope, Olusola ; Ewumi, Ebenezer ; Asghar, Muhammad ( July 2021 , 2021 ASEE Virtual Annual Conference)

   Despite efforts to attract and retain more students in engineering and computer science — particularly women and students from underrepresented groups — diversity within these educational programs and the technical workforce remains stubbornly low. Research shows that undergraduate retention, persistence, and success in college is affected by several factors, including sense of belonging, task value, positive student-faculty interactions, school connectedness, and student engagement [1], [2]. Kuh [1] found that improvement in persistence, performance, and graduation for students in college were correlated to students’ level of participation in particular activities known as high impact educational practices (HIEP). HIEP include, among others, culminating experiences, learning communities, service learning, study abroad, and undergraduate research; Kuh [1] concluded that these activities may be effective at promoting overall student success. Kuh [1] and others [3] further hypothesized that participation in HIEP may especially benefit students from non-majority groups. Whether and how engineering and computer science students benefit from participating in HIEP and whether students from non-majority groups have access to HIEP activities, however, remain as questions to investigate. In this project, we examine engineering and computer science student participation in HIEP at two public land grant institutions. In this study, we seek to understand how and why students participate in HIEP and how participation affects their persistence and success in engineering and computer science majors. Set within the rural, public land grant university context, this study conceptualizes diversity in a broad sense and includes women, members of underrepresented racial and ethnic groups, first generation college students, adult learners, and nontraditional student as groups contributing to the diversity of academic programs and the technical workforce. 

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