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1. Building a Sense of Community for Freshman Civil Engineering Students

   https://doi.org/10.18260/1-2--36762  

   Marti, Erica ; Khan, Eakalak ; Gajurel, Amit ; Tugadi, Neil Christian ( July 2021 , 2021 ASEE Virtual Annual Conference)

   Across the country, less than two-thirds of engineering students persist and earn a degree in engineering. A considerable amount of research on the topic has been conducted, leading to a few key ideas on why students leave engineering. In particular, disinterest in the curriculum, a limited sense of belonging, perception of inadequate academic ability, and disconnect between learning style and instruction mode are some reasons that students depart engineering. Consequently, many first-year programs aim to address one or more of these issues. The ABC program at XXX seeks to improve undergraduate civil engineering and construction management education, as well as increase retention and graduation by specifically focusing on students and curriculum in the first two years of the civil & environmental engineering and construction management (CEEC/CM) programs. Retention and graduation rates are on the lower side of national averages; therefore, faculty at the institution are taking the lead and making changes within the department. One aspect of the program is community cohesion building (CCB), where first-year students create connections, engage in community and engineering design projects, and gain exposure to CEEC/CM professions. Specific objectives are to increase the sense of learning community among students and between students and faculty, as well as increase retention in the first two years. Through biweekly meetings, participants in CCB build connections with freshman CEEC/CM peers, upper level CEEC/CM undergraduate students, CEEC graduate students, and CEEC/CM faculty. Participants also engage in the engineering design process and compete in a national engineering design challenge geared toward freshman and sophomore students. This paper describes the first one-and-a-half years of CCB implementation of a five-year grant. We present the program structure, challenges, changes, and successes. This information should prove useful to other institutions who are in the process of implementing new first-year programs, especially for institutions who have similar characteristics (i.e., urban setting, commuter school, highly diverse, high proportion of first generation students). Program evaluation focuses on the following items related to CCB objectives: 1) increase in sense of belonging as measured by an increase in social networks (tool: student survey), and 2) increase in CEEC/CM retention between freshman/sophomore and sophomore/junior years (tool: institutional data). 

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2. Building a Sense of Community for Freshman Civil Engineering Students

   Marti, E. J ; Khan, E ; Gajurel, A ; Tugadi, N. C. ( July 2021 , ASEE Annual Conference proceedings)

   null (Ed.)

   Across the country, less than two-thirds of engineering students persist and earn a degree in engineering. A considerable amount of research on the topic has been conducted, leading to a few key ideas on why students leave engineering. In particular, disinterest in the curriculum, a limited sense of belonging, perception of inadequate academic ability, and disconnect between learning style and instruction mode are some reasons that students depart engineering. Consequently, many first-year programs aim to address one or more of these issues. The ABC program at XXX seeks to improve undergraduate civil engineering and construction management education, as well as increase retention and graduation by specifically focusing on students and curriculum in the first two years of the civil & environmental engineering and construction management (CEEC/CM) programs. Retention and graduation rates are on the lower side of national averages; therefore, faculty at the institution are taking the lead and making changes within the department. One aspect of the program is community cohesion building (CCB), where first-year students create connections, engage in community and engineering design projects, and gain exposure to CEEC/CM professions. Specific objectives are to increase the sense of learning community among students and between students and faculty, as well as increase retention in the first two years. Through biweekly meetings, participants in CCB build connections with freshman CEEC/CM peers, upper level CEEC/CM undergraduate students, CEEC graduate students, and CEEC/CM faculty. Participants also engage in the engineering design process and compete in a national engineering design challenge geared toward freshman and sophomore students. This paper describes the first one-and-a-half years of CCB implementation of a five-year grant. We present the program structure, challenges, changes, and successes. This information should prove useful to other institutions who are in the process of implementing new first-year programs, especially for institutions who have similar characteristics (i.e., urban setting, commuter school, highly diverse, high proportion of first generation students). Program evaluation focuses on the following items related to CCB objectives: 1) increase in sense of belonging as measured by an increase in social networks (tool: student survey), and 2) increase in CEEC/CM retention between freshman/sophomore and sophomore/junior years (tool: institutional data). 

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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. Invisibilized Hypervisibility: Black STEM Doctoral Students, HBCUs, and Mentoring

   Merriweather, Lisa ; Lambert, Marah ; Casey, Shaunelle ; Howell, Cathy ; Douglas, Niesha ( August 2022 , ASEE Annual Conference proceedings)

   Background: Even though Historically Black College and Universities (HBCUs) make up only 3% of higher education's institutions, they play a pivotal role in producing Black scientists by virtue of the fact that many received either their undergraduate or doctorate degree from a HBCU. HBCUs are credited with providing a more supportive and nurturing environment that thrives on communal mindsets and practices, emphasizing the importance of relationships, offering opportunities for Black students to "see themselves" as part of the academic and social milieu whereas Historically White Institutions (HWIS) are characterized as being hostile and discriminatory. Mentoring is said to be pivotal in the attainment of the PhD. Mentorships have an inherent gatekeeping mechanism, better positioning those who receive effective mentorships while disadvantaging those who do not. It has potential to harm and marginalize when not engaged with deliberate care and a culturally liberative mindset. Mentoring, when not under the thumb of colonizing mindsets, can contribute to more equitable experiences and outcomes for students who hail from AGEP population groups. Literature has indicated that Black students are less likely to have a mentor or be engaged in effective mentorships. The HBCU narrative of supportive environment is consistently told but has scant empirical validation for Black students pursuing STEM doctoral degrees. In fact, the lure of having faculty and peers who look like you is something of an enigma given that even at HBCUs there are limited numbers of Black faculty in STEM. How are same race, same gender mentorships attained when, not unlike their HWIS counterparts, HBCU STEM faculties have a large number of White and Asian men? If the environment is indeed different at HBCUs, is it different for Black STEM doctoral students? Is STEM doctoral mentoring at HBCUs emblematic of anti-Blackness or is it yet another tool used to oppress marginalized students? Theoretical Framework: Anti-black racism and critical capital theory serve as critical theoretical frameworks and were selected because they highlight the ways violence is enacted through taken for granted colonized practices such as mentoring. Fanon understood that thoughts and mindsets are the progenitors of violence and dehumanization is the process through which violence is enacted. Anti-black racism and critical capital theory can be useful in unearthing the structural inequalities that uphold the current system in place for STEM doctoral learning. Research Design: An embedded multiple qualitative case study research project sought to understand the nature and quality of STEM doctoral mentorships at an HBCU. The analysis on the HBCU subcase asked, how are STEM doctoral mentorships understood by Black STEM doctoral students at HBCUs? Black STEM HBCU students were interviewed and completed a mentoring competency assessment survey. In addition STEM doctoral students from three universities also completed the survey. The qualitative data was analyzed using narrative analysis and the survey data was analyzed using descriptive and inferential statistics. This project is part of a larger NSF AGEP sponsored research study. Research findings: The findings from this study expose that Black STEM doctoral students at HBCUs have not reached the proverbial Promise Land. In spite of being in a space that is more diverse, they manage to simultaneously be invisible and hypervisible. An unmerited sense of assumed cultural belonging was highlighted with students reporting a lack of selfethnic reflectors in their programs. In many ways the systemic and institutional structures on HBCUs with respect to STEM doctoral programming mirrored the colonial structures more often associated with HWIS. Their culture and cultural-based experiences as domestic students as well as their academic strengths were often not recognized by mentors while that of international students were. Three themes were supported by the data: Conspicuous Absence, Race Still Matters, and Invisibilized Hypervisibility. Implications: Better understanding how STEM doctoral mentoring is facilitated at HBCUs holds the promise of informing a mentoring practice that supports cultural liberation instead of cultural degradation and suppression. It becomes one avenue as the “The Call'' suggests to "confront our own complicity in the colonial enterprise" by holding STEM doctoral mentors and the institutions they represent accountable for socially just mentoring practices. Greater intentionality as well as mandated training informed by the study's results are recommended. HBCU faculty doctoral mentors are challenged to be scholar activists who engage mentoring from an advocacy and accomplice framework. The development of STEM scholar activists is the aspiration of more culturally liberative STEM doctoral mentorships. Black students need mentors who are willing and equipped to be advocates and accomplices in their success. 

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5. Benefits of First2 Network immersive bridge programs at Fairmont State University

   https://doi.org/10.55632/pwvas.v95i2.1001  

   Keener, Eliza ( April 2023 , Proceedings of the West Virginia Academy of Science)

   Eliza Keener, Dept of Engineering Technology, Fairmont State University, Fairmont, WV 26554, and Landon Brewer, Dept of Natural Sciences, Fairmont State University, Fairmont, WV 26554. Benefits of First2 Network immersive bridge programs at Fairmont State University.    The First2 Network’s Immersion program at Fairmont State University provides a college bridge experience for incoming students in science, technology and engineering and math (STEM). The First2 Network’s goal is to guide and assist rural, first-generation, and other underrepresented STEM college students. The summer immersion bridge experience immerses students into college life. Students stay in dorms and learn what it’s like to be away from home while engaging in a program which includes real research projects in collaboration with professors and peer mentors, introductions to campus resources, and social events. This program helps students get acclimated to college, making it an easier adjustment. The immersive experience also provides connections and a safe space that students can go to when they have questions or need help.     As students who attended the immersive program during the summer of 2022, we can say that it helped us greatly. Not only did we learn about all the resources on campus, but we got real lab experience. We were lab partners conducting analytical chemistry research on lead in paint. We performed all the lab work with supervision and guidance from chemistry professors and lab assistants. At the end of the 2 weeks, we presented our research to students, faculty, and family members. This immersion program was resume and experience building, that helped us make connections with our peers that a have persisted throughout our first year. 

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