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1. Identifying Predictors of HBCU Success in Broadening Participation in STEM: A Case Study Approach

   Jaeger, E.; McKayle, C.; Engerman, K.; Boncana, M.; Joseph, C.; Askew, K. (July 2021, The journal of Negro education)

   Taylor, O.; Campone, F.; Retland, N. (Ed.)

   Historically Black colleges and universities (HBCUs) are noted for their success in broadening participation in science, technology, engineering, and mathematics (STEM). A multiple case study approach was used to identify institutional and leadership characteristics that may drive the success of small HBCUs in broadening participation in STEM. Data on 15 HBCUs were obtained from websites, including institutional websites, and the Integrated Postsecondary Education Data System (IPEDS). Factors common to many institutions included external STEM education funding, STEM-/research-focused missions, commitment of leaders to STEM education, partnerships to support STEM education, STEM faculty professional development, and STEM student support strategies. These characteristics also predicted the percentage of STEM graduates. Implications for future research include illuminating the pathways by which institutional and leadership factors influence student outcomes. 

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2. S-STEM as the Culmination of a Multi-Institutional, Multi-Grant Program for the Success of Underrepresented Students

   Rath, K.; Xavier, J.; Menier, A.; Esiason, J.; Gates, A.; Kitanska, D.; Komisaruk, B.; San Miguel, C.; Stein, J.; Tat, F.; et al (April 2023, Understanding Interventions Journal)

   Although numerous programs exist in many institutions of higher education aimed at helping students from underrepresented groups achieve their goals of successfully graduating in a science, technology, mathematics, or engineering (STEM) field and moving on to the next educational level or a career, few are set up to support students across schools, from their entry into postsecondary education at the community college through the completion of their fouryear degree at a university and beyond. Furthermore, few programs are able to offer the full range of support that has been shown to be optimally effective toward promoting student success, as in, for example, the Building Engineering and Science Talent (BEST) model laid out by Chubin and Ward (2009). The reason for this is simple: rarely are the funds available from any given source to allow a program to provide all the supports students need. In this paper, we provide an example of how this problem was (at least partly) solved by the close interaction of two Louis Stokes Alliances for Minority Participation and an S-STEM program, working within the context of other support opportunities at three community colleges and one university in Northern New Jersey. The programs and the mechanisms through which they support students are described and preliminary data examining their impacts are presented. 

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3. STEM Pathway and College Progression: The Link Between Engineering CTE and Postsecondary Outcomes for Students With Learning Disabilities

   https://doi.org/10.1177/00144029241247034  

   Plasman, Jay; Myles, Desmond (May 2024, Exceptional Children)

   Despite growing calls to increase diversity in science, technology, engineering, and mathematics (STEM) fields, students with learning disabilities (SWLDs) remain underrepresented in STEM at the postsecondary level. Considering this call for increased diversity as a means to expand and strengthen STEM success, we used the High School Longitudinal Study of 2009 to explore how participation in engineering career and technical education (E-CTE) links to postsecondary educational outcomes for SWLDs. Particularly, we examined how E-CTE participation relates to postsecondary remedial course taking, enrollment in a 4-year postsecondary institution, and declaration of a STEM major. Results from school fixed-effects estimations suggest that each credit of E-CTE earned is associated with fewer remedial college courses, a higher likelihood of enrolling in a 4-year as opposed to sub-baccalaureate institution, and increased odds of declaring a STEM major. To conclude, we discuss the implications of our findings for both policymakers and practitioners. 

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4. The COVID-19 Pandemic’s Impact on Black or African American Undergraduate STEM+C Students at a Hispanic Serving Institution

   Ashford-Hanserd, Shetay; Franco Carrera, Lillianna; Moreno, Toni; Belcher, Shannon (June 2022, Journal of Negro education)

   The COVID-19 pandemic has created various challenges for all students, regardless of ethnicity. Research reveals how historically minoritized groups have struggled in their educational pursuits due to the pandemic. Black/African American students have encountered increased challenges in learning online, job insecurity, and negative impacts on their health or emotional state. While research indicates these negative influences have adversely affected students’ overall engagement in postsecondary education, literature is scarce regarding how the COVID-19 pandemic has affected Black or African American students in postsecondary science, technology, engineering, mathematics, and computing (STEM+C) education. The purpose of this exploratory study is to understand the influences of COVID-19 on Black/African American STEM+C majors at a Hispanic serving institution. 

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5. Reimagining Standards for Computer Science Education for Primary and Secondary Schools

   https://doi.org/10.1145/3677619.3678121  

   Koressel, Jacob; Twarek, Bryan; Smith, Julie; McGill, Monica (September 2024, ACM)

   The Computer Science Teachers Association (CSTA) K-12 Standards were last updated in 2017, when only six states in the United States had adopted learning standards for primary and secondary education (K-12) computer science. Fast forward to 2024, and 41 states now have K-12 CS standards (and one has high school CS standards only). In preparation for writing an updated set of standards, CSTA is engaging in three stages of work: reimagining CS for high school students, conducting a crosswalk of K-12 CS standards across all 50 states compared to the CSTA standards (2017), and engaging in the technical process of defining final standards content via research and revision. All three stages draw significantly from the community of practitioners, researchers, curriculum designers, postsecondary faculty, and other interested parties. They also draw significantly from research published since the last revision to take into account the current evidence on learning computer science. In this poster, we describe our process for building the groundwork of knowledge for revising the standards, share highlights of the results to date, and describe how this data will be used to inform the upcoming revision of the CSTA standards. 

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