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1. Engaging STEM Transformational Experiences for Early Momentum (ESTEEM)

   Yahdi, Mohammed ; Bracey, Zoe Buck ( November 2019 , National Science Foundation -  Hispanic-Serving Institutions (HSI) Program Principal Investigator (PI) Meeting, November 2019.)

   Need/Motivation (e.g., goals, gaps in knowledge) The ESTEEM implemented a STEM building capacity project through students’ early access to a sustainable and innovative STEM Stepping Stones, called Micro-Internships (MI). The goal is to reap key benefits of a full-length internship and undergraduate research experiences in an abbreviated format, including access, success, degree completion, transfer, and recruiting and retaining more Latinx and underrepresented students into the STEM workforce. The MIs are designed with the goals to provide opportunities for students at a community college and HSI, with authentic STEM research and applied learning experiences (ALE), support for appropriate STEM pathway/career, preparation and confidence to succeed in STEM and engage in summer long REUs, and with improved outcomes. The MI projects are accessible early to more students and build momentum to better overcome critical obstacles to success. The MIs are shorter, flexibly scheduled throughout the year, easily accessible, and participation in multiple MI is encouraged. ESTEEM also establishes a sustainable and collaborative model, working with partners from BSCS Science Education, for MI’s mentor, training, compliance, and building capacity, with shared values and practices to maximize the improvement of student outcomes. New Knowledge (e.g., hypothesis, research questions) Research indicates that REU/internship experiences can be particularly powerful for students from Latinx and underrepresented groups in STEM. However, those experiences are difficult to access for many HSI-community college students (85% of our students hold off-campus jobs), and lack of confidence is a barrier for a majority of our students. The gap between those who can and those who cannot is the “internship access gap.” This project is at a central California Community College (CCC) and HSI, the only affordable post-secondary option in a region serving a historically underrepresented population in STEM, including 75% Hispanic, and 87% have not completed college. MI is designed to reduce inequalities inherent in the internship paradigm by providing access to professional and research skills for those underserved students. The MI has been designed to reduce barriers by offering: shorter duration (25 contact hours); flexible timing (one week to once a week over many weeks); open access/large group; and proximal location (on-campus). MI mentors participate in week-long summer workshops and ongoing monthly community of practice with the goal of co-constructing a shared vision, engaging in conversations about pedagogy and learning, and sustaining the MI program going forward. Approach (e.g., objectives/specific aims, research methodologies, and analysis) Research Question and Methodology: We want to know: How does participation in a micro-internship affect students’ interest and confidence to pursue STEM? We used a mixed-methods design triangulating quantitative Likert-style survey data with interpretive coding of open-responses to reveal themes in students’ motivations, attitudes toward STEM, and confidence. Participants: The study sampled students enrolled either part-time or full-time at the community college. Although each MI was classified within STEM, they were open to any interested student in any major. Demographically, participants self-identified as 70% Hispanic/Latinx, 13% Mixed-Race, and 42 female. Instrument: Student surveys were developed from two previously validated instruments that examine the impact of the MI intervention on student interest in STEM careers and pursuing internships/REUs. Also, the pre- and post (every e months to assess longitudinal outcomes) -surveys included relevant open response prompts. The surveys collected students’ demographics; interest, confidence, and motivation in pursuing a career in STEM; perceived obstacles; and past experiences with internships and MIs. 171 students responded to the pre-survey at the time of submission. Outcomes (e.g., preliminary findings, accomplishments to date) Because we just finished year 1, we lack at this time longitudinal data to reveal if student confidence is maintained over time and whether or not students are more likely to (i) enroll in more internships, (ii) transfer to a four-year university, or (iii) shorten the time it takes for degree attainment. For short term outcomes, students significantly Increased their confidence to continue pursuing opportunities to develop within the STEM pipeline, including full-length internships, completing STEM degrees, and applying for jobs in STEM. For example, using a 2-tailed t-test we compared means before and after the MI experience. 15 out of 16 questions that showed improvement in scores were related to student confidence to pursue STEM or perceived enjoyment of a STEM career. Finding from the free-response questions, showed that the majority of students reported enrolling in the MI to gain knowledge and experience. After the MI, 66% of students reported having gained valuable knowledge and experience, and 35% of students spoke about gaining confidence and/or momentum to pursue STEM as a career. Broader Impacts (e.g., the participation of underrepresented minorities in STEM; development of a diverse STEM workforce, enhanced infrastructure for research and education) The ESTEEM project has the potential for a transformational impact on STEM undergraduate education’s access and success for underrepresented and Latinx community college students, as well as for STEM capacity building at Hartnell College, a CCC and HSI, for students, faculty, professionals, and processes that foster research in STEM and education. Through sharing and transfer abilities of the ESTEEM model to similar institutions, the project has the potential to change the way students are served at an early and critical stage of their higher education experience at CCC, where one in every five community college student in the nation attends a CCC, over 67% of CCC students identify themselves with ethnic backgrounds that are not White, and 40 to 50% of University of California and California State University graduates in STEM started at a CCC, thus making it a key leverage point for recruiting and retaining a more diverse STEM workforce. 

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2. Explaining Choice, Persistence, and Attrition of Black Students in Electrical, Computer, and Mechanical Engineering: Year 3

   Mobley, Catherine ; Orr, Marisa ; Brawner, Catherine E. ; Brent, Rebecca ( July 2021 , Proceedings of the 2021 American Society of Engineering Education Annual Conference)

   Our transformative mixed-methods project, funded by the Division of Engineering Education and Centers, responds to calls for more cross-institutional qualitative and longitudinal studies of minorities in engineering education. We seek to identify the factors that promote persistence and graduation as well as attrition for Black students in Electrical Engineering (EE), Computer Engineering (CpE), and Mechanical Engineering (ME). Our work combines quantitative exploration and qualitative interviews to better understand the nuanced and complex nature of retention and attrition in these fields. We are investigating the following overarching research questions: 1. Why do Black men and women choose and persist in, or leave, EE, CpE, and ME? 2. What are the academic trajectories of Black men and women in EE, CpE, and ME? 3. In what ways do these pathways vary by gender or institution? 4. What institutional policies and practices promote greater retention of Black engineering students? In this paper, we report on the results from 79 in-depth interviews with students at Predominantly White Institutions (PWIs) and a Historically Black University (HBCU [or HBU]). We describe emergent findings during Year 3 of our project, with a focus on four papers-in-progress: • Paper # 1: Our project utilized several innovative strategies for collecting narratives from our 79 interviewees. In particular, we developed a card-sorting activity to learn more about students’ reasons for choosing their engineering major. We have explored a variety of ways to analyze the data that illustrate the value of this type of data collection strategy and which will be of value to other researchers interested in decision making where there is a potentially complex set of factors, such as those found in deciding on a major. • Paper # 2: We summarized student responses to a pre-interview climate survey about three domains – Teaching and Learning, Faculty and Peer Interactions, and Belonging and Commitment. We investigated two questions: Are there differences between persisters and switchers? And, are there differences by study major? Results indicate substantial differences between persisters and switchers and some differences between ME and ECE students. • Paper # 3: Preliminary analysis of interviews of 10 HBCU Black students and 10 PWI Black students revealed that students enact several different types of community cultural wealth, particularly family, navigational, aspirational, social and resistant capital. Early results suggest that the HBCU students enacted a different form of family capital that resided in their “HBCU family” and the opportunities that their college-based networks afforded them to succeed in the major. PWI students described various forms of navigational capital and assets that were enacted in order to succeed at their study institutions. Our paper concludes with implications for university policies and practices aimed toward underrepresented students. 

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3. Work in Progress: NSF S-STEM Program: Recruitment, Engagement, and Retention: Energizing and Supporting Students with Diverse Backgrounds in Mechanical Engineering

   Jamie R. Gurganus, Liang Zhu ( June 2019 , ASEE annual conference & exposition)

   Recognizing current and future needs for a diverse skilled workforce in mechanical engineering and the rising cost of higher education that acts as a barrier for many talented students with interests in engineering, the NSF funded S-STEM project at a state university focuses resources and research on financial support coupled with curricular and co-curricular activities designed to facilitate student degree attainment, career development, and employability in STEM-related jobs. This program has provided enhanced educational opportunities to more than 90 economically disadvantaged and academically talented undergraduate students in the Mechanical Engineering Department in the past eight years. It is expected that approximately 45 academically talented and financially needy students, including students transferring from community colleges to four-year engineering programs will receive scholarship support in the next 5 years, with an average amount of $6,000 per year for up to four years to earn degrees in mechanical engineering at the University of Maryland Baltimore County (UMBC). Through scholarships and supplemental support services, this program promotes full-time enrollment and will elevate the scholastic achievement of the S-STEM scholars, with a special emphasis on females and/or underrepresented minorities. It will provide a holistic and novel educational experience combining science, engineering, technology and medicine to improve student retention and future career prospects. The project builds on an established partnership between the state university and community colleges to improve and investigate the transfer experience of community college students to four-year programs, student retention at the university, and job placement and pathways to graduate school and employment. A mixed methods quantitative and qualitative research approach will examine the implementation and outcomes of proactive recruitment; selected high impact practices, such as orientation, one-to-one faculty mentoring, peer mentoring, and community building; participation by students in research-focused activities, such as research seminars and undergraduate experiences; and participation by students in career and professional development activities. In this paper, preliminary data will be presented discussing the attitudes and perceptions of the s-stem scholars and comparing students in scholarly programs and non-programmed situations. This research was supported by an NSF S-STEM grant (DUE-1742170). 

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4. NSF S-STEM Program: Recruitment, Engagement, and Retention: Energizing and Supporting Students with Diverse Backgrounds in Mechanical Engineering (Work-in-Progress)

   Jamie R. Gurganus, Liang Zhu ( June 2019 , ASEE annual conference & exposition)

   Recognizing current and future needs for a diverse skilled workforce in mechanical engineering and the rising cost of higher education that acts as a barrier for many talented students with interests in engineering, the NSF funded S-STEM project at a state university focuses resources and research on financial support coupled with curricular and co-curricular activities designed to facilitate student degree attainment, career development, and employability in STEM-related jobs. This program has provided enhanced educational opportunities to more than 90 economically disadvantaged and academically talented undergraduate students in the Mechanical Engineering Department in the past eight years. It is expected that approximately 45 academically talented and financially needy students, including students transferring from community colleges to four-year engineering programs will receive scholarship support in the next 5 years, with an average amount of $6,000 per year for up to four years to earn degrees in mechanical engineering at the University of Maryland Baltimore County (UMBC). Through scholarships and supplemental support services, this program promotes full-time enrollment and will elevate the scholastic achievement of the S-STEM scholars, with a special emphasis on females and/or underrepresented minorities. It will provide a holistic and novel educational experience combining science, engineering, technology and medicine to improve student retention and future career prospects. The project builds on an established partnership between the state university and community colleges to improve and investigate the transfer experience of community college students to four-year programs, student retention at the university, and job placement and pathways to graduate school and employment. A mixed methods quantitative and qualitative research approach will examine the implementation and outcomes of proactive recruitment; selected high impact practices, such as orientation, one-to-one faculty mentoring, peer mentoring, and community building; participation by students in research-focused activities, such as research seminars and undergraduate experiences; and participation by students in career and professional development activities. In this paper, preliminary data will be presented discussing the attitudes and perceptions of the s-stem scholars and comparing students in scholarly programs and non-programmed situations. This research was supported by an NSF S-STEM grant (DUE-1742170). 

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5. Theory to Practice: Faculty Professional Development to integrate Culturally Responsive Pedagogy and Practices in STEM Education to improve success of underserved students in STEM

   Pickering, Cynthia K. ; Rodriguez, Juan R. ; Belknap, Sarah ; Lopez, Mara ; Craft, Elaine ; VanIngen-Dunn, Caroline ; Miller McNeill, Laurie S. ( July 2023 , Proceedings ASEE annual conference)

   The Hispanic Serving Institution Advanced Technological Education Hub 2 (HSI ATE Hub 2) is a three-year collaborative research project funded by the National Science Foundation (NSF) that builds upon the successful outcomes of two mentoring and professional development (PD) programs in a pilot that translates foundational theory related to culturally responsive pedagogy into practice using a 3-tier scaffolded faculty PD model. The goal of HSI ATE Hub 2 is to improve outcomes for Latinx students in technician education programs through design, development, pilot, optimization, and dissemination of this model at 2-year Hispanic Serving Institutions (HSIs). The tiered PD model has been tested by two faculty cohorts at Westchester Community College (WCC), an HSI in the State University of New York (SUNY) system. In year one, Cohort A piloted the PD modules in Tier 1 which featured reflective exercises and small culturally responsive activities to try with their STEM students. In year two, Cohort A piloted the PD modules in Tier 2 and peer-mentored Cohort B as they piloted optimizations introduced to Tier 1 from Cohort A feedback. Three types of optimizations came from faculty feedback. The first considered feedback regarding delivery and/or nature of the content that influenced a subsequent module. The second involved making changes to a particular module before it was delivered to another faculty cohort. The third takes into account what worked and what didn’t to decide which content to bring into virtual webinars for the broader advanced technician education community. Dissemination of the tiered PD model has been achieved in annual webinars with the broader ATE community and at conferences for advanced technician educators to achieve broader impacts in the ATE Community. Longer term, providing professional development in culturally responsive pedagogy and practices can help existing and future faculty learn to productively engage their students in more inclusive ways. As faculty mindsets shift to asset-based thinking and a climate of mutual respect is developed, the learning environment for all students in technician education programs will improve. When students learn in a supportive environment, their chances for success increase. The professional development provided in the HSI ATE Hub 2 project will lead to longer term improvements in four ways: 1) Retainment of Culturally responsive practices by those directly engaged after the project ends; 2) Inserting top activities from the PD into national webinars to extend the reach of the training; 3) Strengthening grant proposals as faculty integrate culturally responsive strategies, knowledge and experience within their ATE proposals to the NSF; and 4) Meeting industry demand for a diverse technician workforce. This second paper in a three-part series describes ongoing progress and lessons learned in developing and piloting the 3-Tier PD model with two Cohorts of STEM faculty at a 2-year HSI. 

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