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The S-STEM supported program “Achieving Change in our Communities for Equity and Student Success” (ACCESS) in STEM started at the University of Washington Tacoma in 2018 and has supported 108 students over 6 cohorts. University of Washington Tacoma has been designated an Asian American and Native American Pacific Islander-serving institution (AANAPISI) due to our high proportion of racial minority and first generation college students. The program is multidisciplinary across STEM majors including Mathematics, Environmental Science, Biomedical Sciences, Information Technology, Computer Science and Systems, Computer Engineering and Systems, Electrical Engineering, Mechanical Engineering, and Civil Engineering, with Computer Science, IT and Engineering representing 65% of ACCESS scholars to date. Program scholars receive full scholarships for their first two years, and partial scholarships for their third and fourth years. We provide a summer bridge precalculus or research experience course, and project-based Introduction to Engineering or Introduction to Research courses in students’ first year. Individual faculty mentoring, an on-campus STEM living learning community,and quarterly Success in STEM seminar courses help scholars form a cohesive community through group mentoring, to promote a sense of belonging, identity, and empowerment in the STEM community. Our S-STEM program is distinctive in focusing on pre-STEM majors in their first and second years on campus to facilitate the entry into STEM majors, and we provide mentor training for ~30-40 faculty in teaching and mentoring diverse student populations, thus impacting all students in our majors. Our goal was to evaluate how retention and academic success of our program scholars was impacted by the program, and whether this program helps to close equity gaps for students who identify as low socioeconomic status, underrepresented minorities, women or non-binary, or first generation in college . We also evaluated the impact of the program for students before, during, and after the Covid-19 pandemic. We compared our program scholars to a comparison group of students who met eligibility requirements but did not participate in the program. Overall, program scholars had higher first and second year retention, and significantly higher GPAs, particularly for individuals belonging to groups that are historically underrepresented in STEM. Retention was markedly higher for program scholars during the pandemic, suggesting that the program may have been particularly impactful for students as they endured the emotional and financial stresses of the pandemic.
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Building Interdisciplinarity in Engineering Doctoral Education: Insights from DTAIS Summer Incubator
In 2021 GW Engineering was awarded funding to launch an interdisciplinary program on trustworthy AI. Designing Trustworthy AI in Systems (or DTAIS) brings together PhD students from systems engineering and computer science to co-design research and tackle the conceptual and methodological bridge building that cross disciplinary work demands. This paper focuses on how this work has been accomplished thus far, in the context of the cornerstone summer incubator, and shares some of the lessons learned. The 10-week summer incubator course, which was designed specifically for this program, brings systems engineers and computer science PhD students to make sense of “AI in the wild” (real world settings) and build short-run research prototypes together. Leveraging the interdisciplinarity of the core program faculty, the group established a fertile middle ground where a mixed method ethos, design sprint rhythm and intentional sense of community enlivens the normative student-advisor modality most PhD students experience. Along the way, the definitional challenge of what is meant exactly by trust and trustworthiness within a particular problem domain and literature is given plenty of room to form, fall apart and form again through discussion, practice, and reflection. With two iterations of the summer incubator course to glean from, we report on the difficulties of rewiring student-advisor dynamics and the positive effects of growing a diverse community. This represents a potential roadmap for how to scaffold interdisciplinarity in engineering doctoral education.
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- Award ID(s):
- 2125677
- PAR ID:
- 10522680
- Publisher / Repository:
- ASEE Conferences
- Date Published:
- Format(s):
- Medium: X
- Location:
- George Washington University, District of Columbia
- Sponsoring Org:
- National Science Foundation
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Achieving Change in our Communities for Equity and Student Success (ACCESS) in STEM at the University of Washington Tacoma started as a Track 1 S-STEM program in 2018 and has supported 69 students to date. This year we received Track 2 funding and welcomed our fifth cohort to campus, with funding to support ~32 additional students through 2026. University of Washington Tacoma is an Asian American and Native American Pacific Islander-serving institution (AANAPISI), and we serve a high proportion of racial minority and first generation college students. Our ACCESS scholars are pursuing bachelor’s degrees in Mathematics, Environmental Science, Biomedical Sciences, Information Technology, Computer Science and Systems, Computer Engineering and Systems, Electrical Engineering, Mechanical Engineering, and Civil Engineering, with Computer Science and Engineering representing over 60% of ACCESS scholars to date. First-time college students and first-year transfer students receive full scholarships for their first two years, and partial scholarships for their third and fourth years. The project includes an optional Early Fall Math course to enhance entry into STEM majors, and participants are able to engage in a Research Experience or project-based Introduction to Engineering course in their first year. Coupled with individual faculty mentoring and an on-campus STEM living learning community, the quarterly Success in STEM seminar course helps scholars form a cohesive community through group mentoring, as well as develop a sense of belonging, identity, and empowerment to transform the culture of STEM. This program is distinguished by its focus on pre-STEM majors in their first and second years on campus, and includes mentor training for ~30-40 faculty in teaching and mentoring diverse student populations, thus impacting all students in our majors. Our goal was to evaluate the effectiveness of a program that focuses on the first two years of college and provides financial support, courses to introduce students to research and project-based engineering, and intensive mentoring in increasing retention and academic success for Computer Science and Engineering (CS+E) students, and whether this program helps to close equity gaps for CS+E students who are low socioeconomic status (SES), underrepresented minorities (URMs), female, and/or first generation in college (First Gen) students. We compared our student scholars to a comparison group of students who met eligibility requirements but did not participate in the program. Program scholars had higher first and second year retention, and had significantly higher GPAs. The pandemic resulted in significant social, emotional, and economic stresses for our program scholars, which may have heightened the impact of the ACCESS in STEM program.more » « less
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- Free Publicly Accessible Full Text
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Accepted Manuscript1.0
- Conference Paper:
- https://doi.org/10.18260/1-2--45707
