skip to main content


Title: Early Academic Momentum: Factors Contributing to Community College Transfer Students’ STEM Degree Attainment
Guided by the notion of academic momentum, this study drew data from longitudinal transcript records at a large public 4-year research university and examined factors that specifically contribute to community college transfer students’ academic momentum. It also explored how early academic momentum along with students’ sociodemographic characteristics impact degree attainment in science, technology, engineering, and mathematics (STEM) fields of study. This study conducted multinomial logistic regression analysis and found that certain students’ background characteristics (i.e., gender, age, and family income), community college academic achievement (i.e., associate degree completion, and number of community college credits accepted), and early academic performance at the 4-year university (math and English preparedness, number of credit hours attempted, and first-semester grade point average) were significantly related to transfer students’ likelihood of obtaining a STEM degree. The findings provide new knowledge about academic momentum and could be used to enhance the community college pathway to STEM degree completion.  more » « less
Award ID(s):
1652622
NSF-PAR ID:
10344749
Author(s) / Creator(s):
Date Published:
Journal Name:
Journal of College Student Retention: Research, Theory & Practice
Volume:
23
Issue:
4
ISSN:
1521-0251
Page Range / eLocation ID:
873 to 902
Format(s):
Medium: X
Sponsoring Org:
National Science Foundation
More Like this
  1. 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. 
    more » « less
  2. A combination of strategies was implemented to reduce barriers to transfer from associate to baccalaureate programs, and baccalaureate degree completion. These strategies include creation of the STEM Transfer Collaborative (STC). an adaption of the CUNY Pathways articulation initiative. Components of the STC include articulation agreements, shared professional development to align pedagogy and curriculum, outreach and collaboration by both the sending and receiving college faculty to begin transfer preparation and support before transfer occurs, and regular updates to community college faculty on the success of their transfer students. The second strategy employed is Momentum to the Baccalaureate (MB), an adaption of the CUNY Accelerated Study in Associate Programs (ASAP). MB provides support for junior and senior-level transfer students who are either community colleges associate degree graduates (external transfer) or associate degree graduates who transferred to bachelor’s programs at the same comprehensive college they earned their associate degree at, which has a 2+2 degree structure (internal transfer). Components of MB include personalized mentoring, advisement, and monthly stipends to students who maintain full-time enrollment and good academic standing. Participating majors include computer engineering technology, computer systems technology, construction management and civil engineering technology, electrical engineering technology, and applied chemistry. Propensity matching was used to evaluate the effectiveness of these strategies. Participating campuses are part of the City University of New York (CUNY), and include six community colleges (Borough of Manhattan Community College, Bronx Community College, Guttman Community College, Hostos Community College, Kingsborough Community College, and LaGuardia Community College), five of which are Hispanic Serving Institutions (HSIs), and New York City College of Technology (City Tech), also an HSI, which offers associate and bachelor’s programs (2+2 structure). Our first cohort of 40 students started upper-level studies in fall 2019, and has completed 2 years (four semesters) of post-associate degree study. The second cohort of 40 students, started in fall 2020, and has completed one year (two semesters) of post-associate degree study. Cohort 1 students receiving MB, supports had a significantly higher graduation rate after two years than the college average. Additionally, for cohort 1, the STC seems to have reduced “transfer shock,” the typical drop in GPA the first semester after transfer. There was no statistical difference in GPA, credits completed and semester-to-semester persistence of internal and external transfers in the MB program. Cohort 1 external transfer students who received support though MB also had a statistically significant improvement in their semester GPAs for their first 3 semesters at City Tech compared to matched students who were not provided support in the junior and senior years. There was no statistically significant difference by the 4th semester. Cohort 2 internal transfers receiving MB supports in their junior year had a statistically significant improvement in credits earned and persistence compared to a matched cohort without MB supports. There was no statistically significant improvement of external transfers compared to a matched cohort, who did not receive MB supports The inability of external transfer students to come to campus due to the pandemic, may have negated the sense of community and belonging that MB was intended to create. Overall, these preliminary results suggest that targeted pre-transfer and post-transfer supports improve transfer student outcomes. This project (NSF grant #1832457) was funded through the NSF Division of Education, Improving Undergraduate STEM Education: Hispanic-Serving Institutions Program. 
    more » « less
  3. According to the National Science Foundation, 50% of Black engineering students who have received a bachelor’s and master’s degree attended a community college at some point during their academic career. However, while research highlights the importance of supporting underrepresented racial and ethnic minorities (URMs) in STEM disciplines, there is a dearth of literature focusing on URMs in community colleges who pursue engineering and other science/math-based majors. Further, Black undergraduates in community colleges are often homogenized by area of study, with little regard for their specific major/discipline. Similarly, while engineering education research has begun to focus on the population of community college students, less attention has been paid to unpacking the experiences of racial subgroups of community college attendees. The engineering student transfer process has specific aspects related to it being a selective and challenging discipline (e.g., limited enrollment policies, engineering culture shock) that warrants a closer investigation. The purpose of this paper is to examine the experiences of a small population of students who have recently transferred from several community colleges to one four-year engineering school. Specifically, we will present preliminary findings derived from interviews with three Black students who started their academic careers at several community colleges in a Mid-Atlantic state, before transferring to the flagship institution of that same state. Interview transcripts will undergo a thorough analysis and will be coded to document rich themes. Multiple analyses of coded interview data will be performed by several members of the research team, as well as external evaluation members who are leading scholars in STEM and/or transfer education research. This research is part of a larger-scale, three year qualitative study, which will examine the academic trajectories of two distinct groups of Blacks in engineering majors: 1) Blacks born and educated in the United States and 2) Those born and educated in other countries. By looking at these populations distinctly, we will build upon past literature that disaggregates the experiences of Black STEM students who represent multiple identities across the African diaspora. Through this lens, we hope to highlight the impact that cultural background may have on the transfer experience. The theoretical framework guiding this study posits that the persistence of Black transfer students in engineering is a longitudinal process influenced by the intersection of both individual and institutional factors. We draw from the STEM transfer model, noting that the transfer process commences during a student’s community college education and continues through his/her transfer and enrollment in an engineering program at a four-year institution. The following factors contribute to our conceptualization of this process: pre-college background, community college prior to transfer, initial transfer to the four-year university, nearing 4-year degree completion. 
    more » « less
  4. This project will contribute to the national need for well-educated scientists, mathematicians, engineers, and technicians by supporting the retention and graduation of high-achieving, low-income students with demonstrated financial need at Minnesota State University, Mankato. Over its six year duration, this project will fund scholarships to 120 unique full-time students who are pursuing Bachelor of Science degrees in engineering. First semester junior, primarily transfer, students at Iron Range Engineering will receive scholarships for one semester. The Iron Range Engineering (IRE) STEM Scholars Program provides a financially sustainable pathway for students across the nation to graduate with an engineering degree and up to two years of industry experience. Students typically complete their first two years of engineering coursework at community colleges across the country. Students then join IRE and spend one transitional semester gaining training and experience to equip them with the technical, design, and professional skills needed to succeed in the engineering workforce. During the last two years of their education, IRE students work in industry, earning an engineering intern salary, while being supported in their technical and professional development by professors, learning facilitators, and their own peers. The IRE STEM Scholars project will provide access to a financially responsible engineering degree for low-income students by financially supporting them during the transitional semester, which has two financial challenges: university tuition costs are higher than their previous community college costs, and the semester occurs before they are able to earn an engineering co-op income. In addition, the project will provide personalized mentorship throughout students’ pathway to graduation, such as weekly conversations with a mentor. By providing these supports, the IRE STEM Scholars project aims to prepare students to be competitive applicants for the engineering workforce with career development and engineering co-op experience. Because community colleges draw relatively representative proportions of students from a variety of backgrounds, this project has the potential to learn how transfer pathways and co-op education can support financially sustainable pathways to engineering degrees for a more diverse group of students and contribute to the development of a diverse, competitive engineering workforce. The overall goal of this project is to increase STEM degree completion of low-income, high-achieving undergraduates with demonstrated financial need. As part of the scope of this project, a concurrent mixed-methods research study will be done on engineering students’ thriving, specifically their identity, belonging, motivation, and overall wellbeing (or mental and physical health). Student outcomes have previously been measured primarily through academic markers such as graduation rates and GPA. In addition to these outcomes, this project explores ways to better support overall student thriving. This study will address the following research questions: How do undergraduate students’ engineering identity and belongingness develop over time in a co-op-based engineering program? How do undergraduate students’ motivation and identity connect to overall wellbeing in a co-op-based engineering program? In the first year of the IRE STEM Scholars Project, initial interview data describe scholars’ sense of belonging in engineering, prior to their first co-op experiences and survey data describe IRE students’ experiences in co-op and overall sense of belonging. Future work will utilize these values to identify ways to better support the IRE STEM scholars’ identity development as they move into their first co-op experiences. This project is funded by NSF’s Scholarships in Science, Technology, Engineering, and Mathematics program, which seeks to increase the number of low-income academically talented students with demonstrated financial need who earn degrees in STEM fields. It also aims to improve the education of future STEM workers, and to generate knowledge about academic success, retention, transfer, graduation, and academic/career pathways of low-income students. 
    more » « less
  5. Wright College, an open-access community college in northwest Chicago, is an independently accredited institution in the City Colleges of Chicago (CCC) system. Wright is federally recognized Hispanic-Serving Institution (HSI) with the largest enrollment of Hispanic students in Illinois. In 2015 Wright piloted a selective guaranteed admission program to the Grainer College of Engineering at the University of Illinois at Urbana-Champaign (UIUC). Students in the Engineering Pathways (EP) program follow a cohort system with rigorous curriculum aligned to UIUC. From this pilot Wright built programmatic frameworks (one-stop intentional advising; mandatory tutoring, near-peer, faculty and professional mentoring; and access to professional organizations) to support EP students. Initial results were positive: 89% transfer rate and 89% bachelor’s degree completion. Building from the EP frameworks, Wright obtained a National Science Foundation (NSF) HSI research grant to expand programs to non-pathway students. Through the grant, Building Bridges into Engineering and Computer Science, the college developed assessment tools, increased the number of 4-year partnerships, and designed and implemented an Engineering Summer Bridge with curriculum contextualized for the needs of the Near-STEM ready students. These students need one to four semesters of Math remediation before moving into the EP. The college measured the Bridge participants' success through analysis of Math proficiency before and after the Bridge, professional identity (sense of belonging) and self-efficacy (the belief that the students will succeed as engineers). Surveys and case study interviews are being supplemented with retention, persistence, transfer, associate and bachelor degree completion rates, and time for degree completion. The key research question is the correlation of these data with self-efficacy and professional identity measures. Preliminary Results: 1) Sixty percent (60%) of the Bridge participants eliminated the remedial Math requirement completely. (Increased Math proficiency) 2) Engineering admission and enrollment doubled. 4) Increased institutionalized collaborations: the creation of a more programmatic admission, advising, transfer, rigorous curriculum, and other student support services within the College. 5) Increased partnerships with 4-year transfer institutions resulting in the expansion of guaranteed/dual admissions programs with scholarships, paid research experience, dual advising, and students transferring as juniors. 5) Increased diversity in Engineering and Computer Science student population. Wright will share an overview of the Building Bridges into Engineering and Computer Science project, research design, expanded practices, assessments and insights from the development and implementation of this program. The developed frameworks will be applied to provide ALL students at Wright, and at CCC equitable Engineering and Computer Science education. 
    more » « less