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1. Board 105: The Redshirt in Engineering Consortium: Progress and Early Insights

   Riskin, Eve ; Milford, Jana ; Callahan, Janet ; Cosman, Pamela ; Schneider, John ; Pitts, Kevin ; Knaphaus-Soran, Emily ; Llewellyn, Donna ; Delaney, Ann ; Myers, Beth ; et al ( June 2018 , ASEE annual conference & exposition proceedings)

   The NSF-funded Redshirt in Engineering Consortium was formed in 2016 with the goal of enhancing the ability of academically talented but underprepared students coming from low-income backgrounds to successfully graduate with engineering degrees. The Consortium takes its name from the practice of redshirting in college athletics, with the idea of providing an extra year and support to help promising engineering students complete a bachelor’s degree. The Consortium builds on the success of three existing “academic redshirt” programs and expands the model to three new schools. The Existing Redshirt Institutions (ERIs) help mentor and train the new Student Success Partners (SSP), and SSPs contribute their unique expertise to help ERIs improve existing redshirt programs. The redshirt model is comprised of seven main programmatic components aimed at improving the engagement, retention, and graduation of students underrepresented in engineering. These components include: “intrusive” academic advising and support services, an intensive first-year academic curriculum, community-building (including pre-matriculation summer programs), career awareness and vision, faculty mentorship, NSF S-STEM scholarships, and second-year support. Successful implementation of these activities is intended to produce two main long-term outcomes: a six-year graduation rate of 60%-75% for redshirt students, and increased rates of enrollment and graduation of Pell-eligible, URM, and women students in engineering at participating universities. In the first year of the grant (AY 16-17), SSPs developed their own redshirt programs, hired and trained staff, and got their programs off the ground. ERIs implemented faculty mentorship programs and expanded support to redshirt students into their sophomore year. In the second year (AY 17-18), redshirt programs were expanded at the ERIs while SSPs welcomed their first cohorts of redshirt students. This Work in Progress paper describes the redshirt programs at each of the six Consortium institutions, identifying distinctions between them in addition to highlighting common elements. First-year assessment results are presented for the ERIs based on student surveys, performance, and retention outcomes. Ongoing research into faculty experiences is investigating how participation as mentors for redshirt students changes faculty mindsets and instructional practices. Ongoing research into student experiences is investigating how the varied curricula, advising, and cohort models used across the six institutions influence student retention and sense of identity as engineering students. 

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2. 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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3. Framework to Enhance STEM Education for Community College Students

   https://doi.org/10.24018/ejedu.2022.3.3.331  

   Zeid, Abe ; Duggan, Claire ( May 2022 , European Journal of Education and Pedagogy)

   Community colleges (CCs) play a critical role in advancing the education of all learners. Approximately 40% of first-time college freshman begin in Community Colleges. The proposed framework seeks to support and excite CC students to persist in their STEM education to increase the pipeline for the STEM workforce. Its vision is to provide CC students engineering skills and to excite them about engineering research. The framework enables students to spend 10 summer weeks at Northeastern University to increase skills, confidence, and learn firsthand about research. Each student will join a research lab, working with faculty and graduate student mentors. Also, students will be mentored after summer to further support their successful graduation and/or transfer to a 4-year institution and beyond. The site is guided by two of the grand challenges of the National Academy of Engineering: personalized learning and scientific discovery. Unique aspects of the proposed framework include: a hands-on short course in engineering topics and software tools; formal mentor training including modules for mentoring CC students; daily student meetings with mentors; extensive professional development seminars; formal research training including daily reflection journals, poster presentations and technical writing with a faculty member; and recruitment from a unique pool of highly talented URM students. 

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4. The Research Experience for Undergraduates (REU) Principal Investigators (PI) Guide: Development of a best practices website.

   Iglesias Pena, Mariangely ; Gilbert, Stephen B ; Payton, Jamie ( June 2018 , ASEE Annual Conference proceedings)

   With the help of the National Science Foundation (NSF), many Principal Investigators (PIs) have been able to mentor undergraduates through Research Experience for Undergraduates (REU) site awards. These REU sites are critical to the development of future graduate students, but can be challenging to run due to several required skills outside the scope of most faculty members' expertise, e.g., recruiting applicants, navigating the logistics of housing visiting undergraduate students, and tracking student outcomes after their REU experiences. In recent years, REU PIs in NSF's Computer & Information Science & Engineering (CISE) Directorate have come together through PI meetings to share best practices for running a successful REU site. While PIs inevitably take different approaches to running their sites based on their research projects, there is still a need to provide new PIs with guidance on the different aspects of an REU site such as identifying resources that can assist in recruiting women and underrepresented minority applicants, providing training for graduate students acting as mentors, and strategies for keeping a mentoring connection to undergraduate researchers after they return to their home institutions. Currently, REU site preparation and orientation for new PIs is a face-to-face process that requires careful planning and significant travel costs. The REU PI Guide, a set of web-based resources at https://www.vrac.iastate.edu/cise-reu-pi-resources/, was developed to share best practices of experienced PIs and build capacity within the REU PI community in a more scalable and cost-effective way. The REU PI Guide allows PIs to look up advice and guidance when needed and share their own best practices. This paper describes our approach to designing the REU PI Guide. The Guide is a database of documents, examples, and overviews of the different aspects of running an REU site. The Guide was developed by assessing new PIs' needs at an NSF workshop for new PIs, gathering existing resources from experienced PIs, creating and refining a website, and evaluation with new PIs. The website’s content and design will be refined through on-going feedback from PIs and other REU site stakeholders. This site has the potential broader impact to share best practices with REU PIs outside the CISE directorate and significantly ease the process of engaging future scientists via REU sites. 

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5. Advancing undergraduate research through regional community college partnerships at Portland State University

   Rice, A. ; Loikith, P. ; Murry, A. ( December 2023 , Transactions American Geophysical Union)

   Opportunities for undergraduate research in STEM programs at community colleges can be few where lower-division science curriculum emphasizes classroom and laboratory-based learning and research laboratories are limited in number. This is particularly true in the geosciences where specialized programs are extremely rare. Urban serving academic research institutions have a unique role and opportunity to partner with regional community college programs for undergraduate research early-on in student post-secondary educational experiences. Programs built for community college transfer students to urban serving undergraduate programs can serve to integrate students into major programs and help reduce transfer shock. The benefits of exploring research as an undergraduate scholar are numerous and include: building towards mastery of technical skills; developing problem-solving in a real-world environment; reading and digesting scientific literature; analyzing experimental and simulation data; working independently and as part of a team; developing a mentoring relationship with a research advisor; and building a sense of belonging and confidence in a scientific field. However, many undergraduate research internships are targeted towards junior-level STEM majors already engaged in upper-division coursework and considering graduate school which effectively excludes community college students from participating. The Center for Climate and Aerosol Research (CCAR) Research Experience for Undergraduate program at Portland State University serves to help build the future diverse research community. 10-week intern research experiences are paired with an expert faculty mentor are designed for students majoring in the natural/physical sciences but not necessarily with a background in climate or atmospheric science. Additional programmatic activities include: 1-week orientation and training using short courses, faculty research seminars, and hands-on group workshops; academic professional and career development workshops throughout summer; journal club activities; final presentations at end of summer CCAR symposium; opportunities for travel for student presentations at scientific conferences; and social activities. Open to all qualifying undergraduates, since 2014 the program recruits primarily from regional (Northwest) community colleges, rural schools, and Native American serving institutions; recruiting students who would be unlikely to be otherwise exposed to such opportunities at their home institution. Over the past 9 cohorts of REU interns (2014-2019), approximately one third of CCAR REU scholars are community colleges students. Here we present criteria employed for selection of REU scholars and an analysis of selection biases in a comparison of students from community colleges, 4-year colleges, and PhD granting universities. We further investigate differential outcomes in efficacy of the REU program using evaluation data to assess changes over the program including: knowledge, intrinsic motivation, extrinsic motivation, science identity, program satisfaction, and career aspirations. In this presentation, we present these findings along with supportive qualitative analyses and discuss their implications for community college students in undergraduate research programs in geosciences. 

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