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1. 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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2. Work in Progress: Evaluating Teaching Self-Advocacy to Historically Minoritized Graduate Students in STEM

   Carmen M. Lilley Gregory Larnell ( June 2023 , 2023 Association for Engineering Education National Conference)

   Many historically minoritized graduate students, here defined as Women, Latinx and Black/African American students, in Science, Technology, Engineering and Math (STEM) experience unwelcome or even hostile ecosystems or environments. Many of the social expectations are that historically minoritized graduate students in STEM should assimilate or acclimate to the cultural, where assimilation/acclimation are defined as cultural conformation vs. social acceptance of a student authentic self/identity. They may also experience forms of continuous microaggressions and isolation. The effects of chronic external stressors, such as experiencing discrimination and social isolation, on increased mental health disorders and decreased physiological health is well known [1-3]. Yet, evidence-based practices of support systems specifically for graduate students from historically marginalized communities to reduce the effects of climates of intimidation are not common. Indeed, researchers have found that such students “would benefit if colleges and universities attempted to deconstruct climates of intimidation [4]” and it has also been shown that teaching underrepresented minority students empowerment skills can improve academic success [5]. Self-advocacy originates from the American Counseling Association (ACA) and the Learning Disabilities (LD) communities for effective counseling that promotes academic success and is based on a social justice framework [6]. The underlying principle of self-advocacy is that supporting skills and knowledge development in the three areas of self-advocacy leads to a student’s long term participation and ultimately academic success in areas such as post-secondary education and STEM. The pillars of the self-advocacy program are centered on (i) Empowerment, (ii) Promoting self-awareness and (iii) Social Justice and programming in the GRaduate Education for Academically Talented Students (GREATS) is aligned and repeated along these three pillars. The current professional development program is in its third year of implementation and to date twenty-seven students have participated in the program. This work in progress paper outlines the evaluation of a self-advocacy program for historically marginalized graduate students in STEM at the University of Illinois Chicago is a minority serving institution as both an Hispanic Serving Institution (HSI) and an Asian American Native American Pacific Islander Serving Institution (AANAPISI). [1] S. Stansfeld and B. Candy, "Psychosocial work environment and mental health--a meta-analytic review," ed, 2006. [2] E. M. Smith, "Ethnic minorities: Life stress, social support, and mental health issues," The Counseling Psychologist, vol. 13, no. 4, pp. 537-579, 1985. [3] D. M. Frost, K. Lehavot, and I. H. Meyer, "Minority stress and physical health among sexual minority individuals," Journal of behavioral medicine, vol. 38, no. 1, pp. 1-8, 2015. [4] R. T. Palmer, D. C. Maramba, and T. E. Dancy, "A Qualitative Investigation of Factors Promoting the Retention and Persistence of Students of Color in STEM," The Journal of Negro Education, vol. 80, no. 4, pp. 491-504, 2011. [Online]. Available: http://www.jstor.org/stable/41341155. [5] A. R. Dowden, "Implementing Self-Advocacy Training Within a Brief Psychoeducational Group to Improve the Academic Motivation of Black Adolescents," The Journal for Specialists in Group Work, vol. 34, no. 2, pp. 118-136, 2009/04/28 2009, doi: 10.1080/01933920902791937. 

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3. Developing two-year college student engineering technology career profiles

   https://doi.org/10.18260/1-2--36945  

   Frady, K. ; Brown, C. ; High, K. ; Hughes, C. ; O’Hara, R. ; & Huang, S. ( July 2021 , Annual American Society for Engineering Education Conference)

   There is little research or understanding of curricular differences between two- and four-year programs, career development of engineering technology (ET) students, and professional preparation for ET early career professionals [1]. Yet, ET credentials (including certificates, two-, and four-year degrees) represent over half of all engineering credentials awarded in the U.S [2]. ET professionals are important hands-on members of engineering teams who have specialized knowledge of components and engineering systems. This research study focuses on how career orientations affect engineering formation of ET students educated at two-year colleges. The theoretical framework guiding this study is Social Cognitive Career Theory (SCCT). SCCT is a theory which situates attitudes, interests, and experiences and links self-efficacy beliefs, outcome expectations, and personal goals to educational and career decisions and outcomes [3]. Student knowledge of attitudes toward and motivation to pursue STEM and engineering education can impact academic performance and indicate future career interest and participation in the STEM workforce [4]. This knowledge may be measured through career orientations or career anchors. A career anchor is a combination of self-concept characteristics which includes talents, skills, abilities, motives, needs, attitudes, and values. Career anchors can develop over time and aid in shaping personal and career identity [6]. The purpose of this quantitative research study is to identify dimensions of career orientations and anchors at various educational stages to map to ET career pathways. The research question this study aims to answer is: For students educated in two-year college ET programs, how do the different dimensions of career orientations, at various phases of professional preparation, impact experiences and development of professional profiles and pathways? The participants (n=308) in this study represent three different groups: (1) students in engineering technology related programs from a medium rural-serving technical college (n=136), (2) students in engineering technology related programs from a large urban-serving technical college (n=52), and (3) engineering students at a medium Research 1 university who have transferred from a two-year college (n=120). All participants completed Schein’s Career Anchor Inventory [5]. This instrument contains 40 six-point Likert-scale items with eight subscales which correlate to the eight different career anchors. Additional demographic questions were also included. The data analysis includes graphical displays for data visualization and exploration, descriptive statistics for summarizing trends in the sample data, and then inferential statistics for determining statistical significance. This analysis examines career anchor results across groups by institution, major, demographics, types of educational experiences, types of work experiences, and career influences. This cross-group analysis aids in the development of profiles of values, talents, abilities, and motives to support customized career development tailored specifically for ET students. These findings contribute research to a gap in ET and two-year college engineering education research. Practical implications include use of findings to create career pathways mapped to career anchors, integration of career development tools into two-year college curricula and programs, greater support for career counselors, and creation of alternate and more diverse pathways into engineering. Words: 489 References [1] National Academy of Engineering. (2016). Engineering technology education in the United States. Washington, DC: The National Academies Press. [2] The Integrated Postsecondary Education Data System, (IPEDS). (2014). Data on engineering technology degrees. [3] Lent, R.W., & Brown, S.B. (1996). Social cognitive approach to career development: An overivew. Career Development Quarterly, 44, 310-321. [4] Unfried, A., Faber, M., Stanhope, D.S., Wiebe, E. (2015). The development and validation of a measure of student attitudes toward science, technology, engineeirng, and math (S-STEM). Journal of Psychoeducational Assessment, 33(7), 622-639. [5] Schein, E. (1996). Career anchors revisited: Implications for career development in the 21st century. Academy of Management Executive, 10(4), 80-88. [6] Schein, E.H., & Van Maanen, J. (2013). Career Anchors, 4th ed. San Francisco: Wiley. 

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4. Comparative Study of the Intersection of Engineering Identify and Black Identity of African-American Engineering Students at a PWI and an HBCU

   Berhan, L. ; Kumar, R. ; Goodloe, M. ; Jones, J. ; Adams, A. ( June 2018 , ASEE annual conference & exposition)

   This interdisciplinary, inter-institutional research initiation project is motivated by the need to develop practical strategies for broadening the participation of African American students in engineering. The central objective of the project is to conduct a comparative study of the factors affecting the success and pathways to engineering careers of African American students at a Predominantly White Institution (PWI), the University of Toledo, and a Historically Black University (Alabama Agricultural and Mechanical University). Through this research we hope to gain insight into the factors affecting the social and academic well-being of students at PWIs and HBCUs from a psychological and anthropological perspective. For students from underrepresented groups in STEM at both HBCUs and PWIs it is generally recognized that social capital in the form of familial, peer and mentor support is critical to persistence in their major field of study. However, the role that embedded networks within student groups in general, and minority engineering affinity groups in particular, play in engineering students’ identity formation and academic success is not well understood. It is also not clear how other factors including institutional support and the attitudes and beliefs of faculty and staff toward underrepresented minority students affect the ability of these students to integrate into the social and academic systems at their institutions and how these factors influence the formation and development of their identities as engineers. Here we report on the role of membership in organizations for underrepresented minority engineering students such as the National Society of Black Engineers (NSBE) in contributing to the interlinking of personal and professional identities, and to the career pathways of African American students enrolled in PWI and HBCU, respectively. 

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5. How Do Educational Experiences Predict Computing Identity?

   https://doi.org/10.1145/3470653  

   Lunn, Stephanie ; Ross, Monique ; Hazari, Zahra ; Weiss, Mark Allen ; Georgiopoulos, Michael ; Christensen, Kenneth ( June 2022 , ACM Transactions on Computing Education)

   Despite increasing demands for skilled workers within the technological domain, there is still a deficit in the number of graduates in computing fields (computer science, information technology, and computer engineering). Understanding the factors that contribute to students’ motivation and persistence is critical to helping educators, administrators, and industry professionals better focus efforts to improve academic outcomes and job placement. This article examines how experiences contribute to a student’s computing identity, which we define by their interest, recognition, sense of belonging, and competence/performance beliefs. In particular, we consider groups underrepresented in these disciplines, women and minoritized racial/ethnic groups (Black/African American and Hispanic/Latinx). To delve into these relationships, a survey of more than 1,600 students in computing fields was conducted at three metropolitan public universities in Florida. Regression was used to elucidate which experiences predict computing identity and how social identification (i.e., as female, Black/African American, and/or Hispanic/Latinx) may interact with these experiences. Our results suggest that several types of experiences positively predict a student’s computing identity, such as mentoring others, having a job, or having friends in computing. Moreover, certain experiences have a different effect on computing identity for female and Hispanic/Latinx students. More specifically, receiving academic advice from teaching assistants was more positive for female students, receiving advice from industry professionals was more negative for Hispanic/Latinx students, and receiving help on classwork from students in their class was more positive for Hispanic/Latinx students. Other experiences, while having the same effect on computing identity across students, were experienced at significantly different rates by females, Black/African American students, and Hispanic/Latinx students. The findings highlight experiential ways in which computing programs can foster computing identity development, particularly for underrepresented and marginalized groups in computing. 

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