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1. Does EPICS as a Pre-college Program Foster Engineering Identity Development as Correlated to Doing Engineering?

   https://doi.org/10.18260/1-2--34475  

   Ferrone, Ciera ; Ganesh, Tirupalavanam ; Velez, Jennifer ; Collofello, James ; Squires, Kyle ( June 2020 , 2020 ASEE Virtual Annual Conference Content Access)

   Engineering Projects in Community Service (EPICS) is a middle and high school program, with a focus on the engineering design process and delivering real solutions to community partners. In order to evaluate the efficacy of the program, a pre-post test design was implemented to examine changes in attitudinal and behavioral measures. Pre-data were collected at the beginning of the school year, and paralleled the program’s registration process to ensure high response rates; post- data were then collected at the end of the school year. Demographic data demonstrate that of all 2018 - 2019 registered EPICS participants (N = 414), 41 percent were female; 66.6 percent were non-white; and 30 percent held first generation student status. Importantly, 68.5 percent of participants reported that neither parent or guardian is an engineer, and 65.7 percent of participants reported that they “definitely will attend” a four-year university. These data suggest that the current sample is ideal for evaluating EPICS as a pre-college engineering education program, because most participants are not experiencing engineering in the home and may be less susceptible to parental pressures for choosing engineering as a college major and potential career, but have salient intentions to attend college. In addition to collectingmore »demographic information, participants completed a series of measures designed to capture attitudes and behaviors toward engineering as a potential career field. The main measures of interest include Engineering Identity and Doing Engineering. Engineering Identity scores reflect participants’ personal and professional identities as engineers; Doing Engineering scores indicate participants’ prior experience with engineering and its related technical skills. Baseline data on the sample reveal average engineering identities (M = 38.41, SD = 6.44, 95% CI [37.77, 39.05]). A series of t-tests was conducted to examine gender differences in these measures. Men reported significantly higher engineering identities (M = 37.65, SD = 6.58) compared to women (M = 39.54, SD = 6.09), t(360) = 2.95, p = .003, F = .037. Men reported stronger and more frequent experiences with engineering, indicated by their higher Doing Engineering scores (M = 13.75, SD = 5.16), compared to women (M = 15.31, SD = 4.69), t(368) = 3.13, p = .002, F = .003. Interestingly, first generation students reported higher engineering identities (M = 37.45, SD = 6.53) compared to non-first generation students (M = 39.66, SD = 5.99), t(375) = 3.46, p = .001, F = 1.39. To examine the relationship between Engineering Identity and Doing Engineering, a correlation analysis was conducted and a moderate, positive relationship emerged, such that as students’ experience with engineering increased, their engineering identities also increased (R = .463, p > .000).« less
2. Internship Prevalence and Factors Related to Participation

   Atwood, S. A. ; Gilmartin, S. K. ; Mostoller, A. M. ; Chen, H. L. ; Sheppard, S. ( January 2021 , 2021 ASEE Virtual Annual Conference)

   The value of internship experiences for engineering students is widely discussed in the literature. With this analysis, we seek to contribute knowledge addressing 1) the prevalence of internship experiences amongst engineering students drawn from a large, multi-institutional, nationally-representative sample, 2) if the likelihood of having an engineering internship experiences is equitable amongst various student identities, and 3) what additional factors influence the likelihood of a student having an internship experience, such as field of study and institution type. Data were drawn from a 2015 multi-institutional nationally representative survey of engineering juniors and seniors, excluding one institution with a mandatory co-op program (n = 5530 from 26 institutions). A z-test was used to analyze differences in internship participation rates related to academic cohort (e.g., junior, senior), gender, underrepresented minority (URM) status, first-generation, and low-income status, as well as a subset of identities at the intersection of these groups (gender + URM; first-generation + low-income). A logistic regression model further examined factors such as GPA, engineering task self-efficacy, field of engineering, and institution type. We found that amongst the students in our dataset, 64.7% of the seniors had “worked in a professional engineering environment as an intern/co-op” (41.1% of juniors, 64.7% ofmore »5th years). Significantly less likely (p<0.05) to have internship experiences were men compared to women (52.9% vs 58.3%), URM students compared to their majority counterparts (41.5% vs 56.8%), first-generation students compared to continuing (47.6% vs 57.2%), and low-income students compared to higher-income peers (46.2% vs 57.4%). Examined intersectional identities significantly less likely to have an internship were URM men (37.5%) and first-generation low-income students (42.0%), while non-URM women (60.5%) and continuing high-income students (58.2%) were most likely to report having an internship. Results from the logistic regression model indicate that significant factors are cohort (junior vs senior), GPA, engineering task self-efficacy, and engineering field. When controlling for the other variables in the model, gender, URM, first-generation, and low-income status remain significant; however, the interaction effect between these identities is not significant in the full model. Institution type did not have much impact. Having a research experience was not a significant factor in predicting the likelihood of having an internship experience, although studying abroad significantly increased the odds. Amongst engineering fields, industrial and civil engineering students were the most likely to have an internship, while aerospace and materials engineering students were the least likely. Full results and discussion will be presented in the paper. This analysis provides valuable information for a variety of stakeholders. For engineering programs, it is useful to benchmark historic students’ rates of internship participation against a multi-institutional, nationally representative dataset. For academic advisors and career services professionals, it is useful to understand in which fields an internship is common to be competitive on the job market, and which fields have fewer opportunities or prioritize research experiences. Ultimately, for those in higher education and workforce development it is vital to understand which identities, and intersectional identities, are accessing internship experiences as a pathway into the engineering workforce.« less
3. Barriers and supports needed to improve ET career development: A two-year view of D.E.E.P. engineering technology career formation progress and impacts

   https://doi.org/10.18260/1-2--36738  

   Frady, K. ; Hughes, C. ; High, K. ( July 2021 , Annual American Society for Engineering Education Conference)

   The purpose of the Research in the Formation of Engineers National Science Foundation funded project, Developing Engineering Experiences and Pathways in Engineering Technology Career Formation (D.E.E.P. Engineering Technology Career Formation), is to develop a greater understanding of the professional identity, institutional culture, and formation of engineer technicians and technologists (ET) who are prepared at two-year colleges. ET professionals are important hands-on members of engineering teams who have specialized knowledge of components and engineering systems. Little research on career development and the role of ET in the workforce has previously been conducted prompting national organizations such as NSF and the National Academy of Sciences to prompt more research in this area [1]. The primary objectives of this project are to: (a) identify dimensions of career orientations and anchors at various stages of professional preparation and map to ET career pathways, (b) develop an empirical framework, incorporating individual career anchors and effect of institutional culture, for understanding ET professional formation, and (c) develop and pilot interventions aimed at transforming engineering formation systems in ET contexts. The three interdisciplinary theoretical frameworks integrated to guide design and analysis of this research study are social cognitive career theory (SCCT) [2], Schein’s career anchors which focusesmore »on individual career orientation [3], and the Hughes value framework focused on the organization [4]. SCCT which links self-efficacy beliefs, outcome expectations, and personal goals to educational and career decisions and outcomes ties the individual career anchors to the institutional context of the Hughes framework [2]. To date, the project has collected and analyzed quantitative data from over 330 participants who are two-year college ET students, two-year college transfer students, and early career ET professionals. Qualitative data from historical institutional documents has also been collected and analyzed. Initial analyses have revealed gaps and needed areas of support for ET students in the area of professional formation. Thus far, the identified gaps are in institutional policy (i.e. lack of articulation agreements), needed faculty professional development (i.e. two-year faculty on specific career development and professional ET formation needs and four-year faculty on unique needs of transfer students), missing curriculum and resources supporting career development and professional formation of ET students, and integration of transfer student services focusing on connecting faculty and advisors across both institutional levels and types of programs. Significant gaps in the research promoting understanding of the role of ET and unique professional formation needs of these students were also confirmed. This project has been successful at helping to broaden participation in ET engineering education through integrating new participants into activities (new four-year institutional stakeholders, new industry partners, new faculty and staff directly and indirectly working with ET students) and through promoting disciplinary (engineering education and ET) and cross disciplinary collaborations (human resource development, higher education leadership, and student affairs). With one year remaining before completion of this project, this project has promoted a better understanding of student and faculty barriers supporting career development for ET students and identified need for career development resources and curriculum in ET. Words: 498 References [1] National Academy of Engineering. (2016). Engineering technology education in the United States. Washington, DC: The National Academies Press. [2] Lent, R.W., & Brown, S.B. (1996). Social cognitive approach to career development: An overivew. Career Development Quarterly, 44, 310-321. [3] Schein, E. (1996). Career anchors revisited: Implications for career development in the 21st century. Academy of Management Executive, 10(4), 80-88. [4] Hughes, C. (2014, Spring). Conceptualizing the five values of people and technology development: Implications for human resource managmeent and development. Workforce Education Forum, 37(1), 23-44.« less
4. What do Undergraduate Engineering Students and Pre-service Teachers Learn by Collaborating and Teaching Engineering and Coding Through Robotics?

   Kidd, J. ; Kaipa, K. ; Sacks, S. ; Ringleb, S. ; Pazos, P. ; Gutierrez, K. ; Ayala, O. M. ; de Souza Almeida, L. M. ( June 2020 , 2020 ASEE Virtual Annual Conference Content Access, Virtual Online)

   This research paper presents preliminary results of an NSF-supported interdisciplinary collaboration between undergraduate engineering students and preservice teachers. The fields of engineering and elementary education share similar challenges when it comes to preparing undergraduate students for the new demands they will encounter in their profession. Engineering students need interprofessional skills that will help them value and negotiate the contributions of various disciplines while working on problems that require a multidisciplinary approach. Increasingly, the solutions to today's complex problems must integrate knowledge and practices from multiple disciplines and engineers must be able to recognize when expertise from outside their field can enhance their perspective and ability to develop innovative solutions. However, research suggests that it is challenging even for professional engineers to understand the roles, responsibilities, and integration of various disciplines, and engineering curricula have traditionally left little room for development of non-technical skills such as effective communication with a range of audiences and an ability to collaborate in multidisciplinary teams. Meanwhile, preservice teachers need new technical knowledge and skills that go beyond traditional core content knowledge, as they are now expected to embed engineering into science and coding concepts into traditional subject areas. There are nationwide calls to integrate engineeringmore »and coding into PreK-6 education as part of a larger campaign to attract more students to STEM disciplines and to increase exposure for girls and minority students who remain significantly underrepresented in engineering and computer science. Accordingly, schools need teachers who have not only the knowledge and skills to integrate these topics into mainstream subjects, but also the intention to do so. However, research suggests that preservice teachers do not feel academically prepared and confident enough to teach engineering-related topics. This interdisciplinary project provided engineering students with an opportunity to develop interprofessional skills as well as to reinforce their technical knowledge, while preservice teachers had the opportunity to be exposed to engineering content, more specifically coding, and develop competence for their future teaching careers. Undergraduate engineering students enrolled in a computational methods course and preservice teachers enrolled in an educational technology course partnered to plan and deliver robotics lessons to fifth and sixth graders. This paper reports on the effects of this collaboration on twenty engineering students and eight preservice teachers. T-tests were used to compare participants’ pre-/post- scores on a coding quiz. A post-lesson written reflection asked the undergraduate students to describe their robotics lessons and what they learned from interacting with their cross disciplinary peers and the fifth/sixth graders. Content analysis was used to identify emergent themes. Engineering students’ perceptions were generally positive, recounting enjoyment interacting with elementary students and gaining communication skills from collaborating with non-technical partners. Preservice teachers demonstrated gains in their technical knowledge as measured by the coding quiz, but reported lacking the confidence to teach coding and robotics independently of their partner engineering students. Both groups reported gaining new perspectives from working in interdisciplinary teams and seeing benefits for the fifth and sixth grade participants, including exposing girls and students of color to engineering and computing.« less
5. Effects of Research and Internship Experiences on Engineering Task Self-Efficacy on Engineering Students Through an Intersectional Lens.

   Kusimo, A. ; Thompson, M. ; Atwood, S. ; Sheppard, S. ( January 2018 , Proceedings of the American Society for Engineering Education Annual Conference, June 24-27, 2018. Salt Lake City, Utah.)

   High-impact academic experiences, particularly research and internship experiences, have positive impacts for engineering students on engineering task self-efficacy (ETSE), a measure of students’ perception of their ability to perform technical engineering tasks. However, under- represented racial/ethnic minority students (URM) and women in engineering are found to have relatively lower self-perceptions across several academic and professional self-efficacy measures. Previous studies examined the impact of research and internship experiences on ETSE for students categorized by gender and URM status separately. The current study explores the impact of these experiences on ETSE for the intersection between these two identity categories. This study found that both non-URM and URM women that participated in research and internship experiences had lower ETSE scores than non-URM and URM men, respectively. However, URM women that participated in both research and internship experiences had a statistically similar ETSE score to non-URM men that had not participated in either. This study uses multiple linear regression to measure the association between engineering internships and student’s reported ETSE (effects of participating in research were not found to be significant across identities). Preliminary findings indicate that differences in ETSE between internship participants and non-participants are highest for URM women when compared to theirmore »counterparts. Consistent with the literature, this research finds that there is a greater positive effect in ETSE scores, as a result of participation in both research and internship experiences, for URM women than their majority counterparts. These preliminary results provide a foundation for further studies to causally investigate the link between academic experiences and self-efficacy levels for students who are underrepresented in engineering programs. Future implications of this work include the creation of targeted intervention efforts to increase support for all URM students’ access and participation in research and internship experiences. Additionally, this work seeks to challenge the bias towards monolithic interpretations of women and URM engineering students as separate categories and encourage intersectional perspectives when analyzing data to produce more inclusive results. Key Concepts: intersectionality, self-efficacy, engineering task self-efficacy, learning outcomes, academic pathways, inclusion, engineering experiences, research, internships« less