More Like this

1. “Because I’m Not Always Constantly Getting Everything Right”: Gender Differences in Engineering Identity Formation in Elementary Students

   https://doi.org/10.18260/1-2--33967  

   Hoch, Annmarie ; Miel, Karen ; Portsmore, Merredith ; Swanson, Rebecca ( January 2020 , American Society of Engineering Education)

   Developing a strong engineering identity, or sense of belonging in engineering, is essential to pursuing and persisting in the field. Participating in an engineering outreach program is widely seen as an opportunity for youth to ignite and increase an identity as an engineer. As early as elementary school, youth evaluate their experiences, interests, and successes to make choices about possible futures. Although these early experiences and choices influence future participation in, pursuit of, and persistence in engineering, studies of engineering identity development have concentrated on undergraduate and high school learners. This study examines engineering identity development in elementary school students participating in an engineering education outreach program, expanding understanding of early influences on engineering identity formation. This study asks: How do students’ descriptions of their engineering experiences indicate the influence their experiences have on their engineering identity development? This study is embedded in an NSF-funded study of a university-led engineering education outreach program. In this program, pairs of university students facilitated weekly hour-long engineering design challenges in elementary classrooms throughout the school year. At the end of the academic year, we conducted semi-structured interviews with 76 fourth- and fifth-grade students who had participated in the outreach program. The interviewers asked students to rate their enjoyment of and skills in engineering within the context of the program. Iterative qualitative coding was used to elicit emergent patterns in students’ responses and examine them in the context of the Godwin et al (2016) engineering identity framework, using the constructs of interest, performance/competence, and recognition. Responses were then analyzed based on participants’ gender to understand and identify potential differences in influences on engineering identity development. Findings indicate that student talk around interest tended to be more positive, while student talk around performance/competence tended to be more negative, indicating the type of relationships students had with their interest in engineering compared to their perceived skills in doing engineering. However, within the construct of performance/competence, girls used negative language at a higher frequency than boys. Within this construct-based code, there were categories with large variations in positive and negative talk by gender. These gendered patterns provide insight into the differing ways girls and boys interact with engineering and how they start to develop engineering identities. 

   more » « less
2. Findings from the First Year of a Project that Partners Engineers and Educators in Rural Schools

   Grohs, J. R. ; van Montfrans, V. ; Matusovich, H. M. ; Kirk, G. R. ; Carrico, C. ; Gillen, A. L. ; Blackowski, S. A. ; Lesko, H. L. ; Paradise, T. ( June 2018 , ASEE Annual Conference proceedings)

   One significant barrier to broadening participation in engineering and recruiting future engineers is the pervasive lack of understanding or even misunderstanding of what engineering is and what engineers do. The challenges to broadening participation in engineering are further complicated as underrepresented groups often report constructs, such as cultural milieu and outcome expectations, as more important than interest in influencing career choices. Addressing such issues is difficult and single exposure interventions are unlikely to make engineering careers seem more relevant or attainable for most students. More sustainable interventions, designed to (1) challenge misperceptions and create relevant conceptions of engineering; (2) maintain and expand situational interest; and, (3) integrate with individual interests, values, and social identities, appear to hold more promise for creating significant change. As a possible means of developing more sustainable interventions, our ITEST project partners researchers, teachers, and local industry representatives in creating a series (approximately 6 across an academic year) of engineering-related learning activities for middle school children in three school systems in or near rural Appalachia. Across the first year of implementation, we involved nine teachers, six people working at three different companies and more than 500 students with a series of activities in each classroom. To examine the impact of our project, we are using mixed methods, including interviews, surveys, classroom observations, and classroom artifacts gathered from multiple project stakeholders, to answer the following research questions: RQ 1: How do participants conceptualize engineering careers? How and why do such perceptions shift throughout the project? RQ 2: What elements of the targeted intervention affect student motivation towards engineering careers specifically with regard to developing competencies and ability beliefs regarding engineering? RQ 3: How can strategic collaboration between K12 and industry promote a shift in teacher’s conceptions of engineers and increased self-efficacy in building and delivering engineering curriculum? RQ 4: How do stakeholder characteristics, perceptions, and dynamics affect the likelihood of sustainability in strategic collaborations between K12 and industry stakeholders? How do prevailing institutional and collaborative conditions mediate sustainability? Our findings to date offer insights across all research questions and have important implications for stakeholders hoping to raise awareness of engineering among youth, particularly in rural areas. 

   more » « less
3. The effect of engineering summer camps on middle school students interest and identity

   Chatterjee, I ; Kirn, A ; Amos, J ( June 2018 , ASEE annual conference & exposition proceedings)

   A persistent problem in engineering is an insufficient number of students interested in pursuing engineering as a college major and career. Middle school is a critical time where student interest, identity, and career choices begin to solidify. Student interest in engineering at the K-12 level has been shown to predict whether they pursue engineering as a college major and career. Therefore, research is needed to determine if engineering summer camp activities affect engineering interest and identity in middle school students and in this paper, we present a research study approach to achieve the stated objective. To develop engineering-specific theories of how engineers are formed, this paper explores interest and identity development of three middle-school populations participating in engineering summer camps offered by the College of Engineering at a Western land-grant institution: (1) Young women in engineering camp (2) First generation camp and, (3) Introduction to engineering camp. The camps are identical in content and designed with the goal of increasing understanding of different engineering fields and careers. The only difference between the three camps is that the women-focused and first generation camps involve participation of guest speakers and role-model mentors appropriate for the camp populations. The main objective of designing this mixed-methods research study is to answer three research questions: (1) How strongly are engineering identity and interest linked to the intention to pursue engineering as a major in college and as a future career? (2) Which specific activities in the camps lead to a change in identity and interest in engineering? (3) To what extent and in what ways do the qualitative participant focus group interviews and observations of participants engaged in camp activities addressing research question (2) contribute to a comprehensive understanding of the quantitative data obtained via pre- and post-surveys addressing research question (1)? The research design leverages existing quantitative surveys. Additionally, focus groups and observations will be based on a selected set of questions from these surveys. The research design consists of one phase with two data streams. Quantitative data are gathered in Phase 1 from two data collection points: first, when students register for the camp and, second, at the end of the camp (post-survey). Qualitative data in the form of in-depth focus group interviews (at the end of the camp) with 4 – 5 participants per focus group and observations of camp activities during the five days of camp are implemented. For the qualitative analysis, Grounded Theory is utilized for analyzing focus group interview and observation transcripts using an iterative process that involves reading, discussing, and coding. This paper will present details of the quantitative and qualitative analysis methods used for this study. The research is funded by the National Science Foundation PFE:RIEF program. 

   more » « less
4. Integrating Professional Mentorship with a 3D-Printing Curriculum to Help Rural Youth Forge STEM Career Connections.

   Bhaduri, S. ( July 2021 , 2021 ASEE Virtual Annual Conference.)

   Economically disadvantaged youth residing in mountain tourist communities represent an important and understudied rural population. These communities typically include a large percentage of children that are English language learners. Our NSF STEM Career Connections project, A Model for Preparing Economically-Disadvantaged Rural Youth for the Future STEM Workplace, investigates strategies that help middle school youth in these communities to envision a broader range of workforce opportunities, especially in STEM and computing careers. This poster highlights the initial findings of an innovative model that involves working with local schools and community partners to support the integration of local career contexts, engineering phenomena, 3D printing technologies, career connections, and mentorship into formal educational experiences to motivate and prepare rural youth for future STEM careers. We focus on select classrooms at two middle schools and describe the implementation of a novel 3D printing curriculum during the 2020-2021 school-year. Two STEM teachers implemented the five-week curriculum with approximately 300 students per quarter. To create a rich inquiry-driven learning environment, the curriculum uses an instructional design approach called storylining. This approach is intended to promote coherence, relevance, and meaning from the students’ perspectives by using students’ questions to drive investigations and lessons. Students worked towards answering the question: “How can we support animals with physical disabilities so they can perform daily activities independently?” Students engaged in the engineering design process by defining, developing, and optimizing solutions to develop and print prosthetic limbs for animals with disabilities using 3D modeling, a unique augmented reality application, and 3D printing. In order to embed connections to STEM careers and career pathways, some students received mentorship and guidance from local STEM professionals who work in related fields. This poster will describe the curriculum and its implementation across two quarters at two middle schools in the US rural mountain west, as well as the impact on students’ interest in STEM and computing careers. During the first quarter students engaged in the 3D printing curriculum, but did not have access to the STEM career and career pathway connections mentorship piece. During the second quarter, the project established a partnership with a local STEM business -- a medical research institute that utilizes 3D printing and scanning for creating human surgical devices and procedures -- to provide mentorship to the students. Volunteers from this institute served as ongoing mentors for the students in each classroom during the second quarter. The STEM mentors guided students through the process of designing, testing, and optimizing their 3D models and 3D printed prosthetics, providing insights into how students’ learning directly applies to the medical industry. Different forms of student data such as cognitive interviews and pre/post STEM interest and spatial thinking surveys were collected and analyzed to understand the benefits of the career connections mentorship component. Preliminary findings suggest the relationship between local STEM businesses and students is important to motivate youth from rural areas to see themselves being successful in STEM careers and helping them to realize the benefits of engaging with emerging engineering technologies. 

   more » « less
5. Social Dialogue in the Engineering Classroom: The Effect of National Events on the Political and Social Attitudes of First-Year Engineering Students

   Langus, Tara C. ; Pearson, Nelson ; Major, Justin ; Rodríguez-Simmonds, Héctor E. ; Godwin, Allison ; Kirn, Adam ( January 2018 , ASEE annual conference & exposition)

   This research paper focuses on the effect of recent national events on first-year engineering students’ attitudes about their political identity, social welfare, perspectives of diversity, and approaches to social situations. Engineering classrooms and cultures often focus on mastery of content and technical expertise with little prioritization given to integrating social issues into engineering. This depoliticization (i.e., the removal of social issues) in engineering removes the importance of issues related to including diverse individuals in engineering, working in diverse teams, and developing cultural sensitivity. This study resulted from the shift in the national discourse, during the 2016 presidential election, around diversity and identities in and out of the academy. We were collecting interview data as a part of a larger study on students attitudes about diversity in teams. Because these national events could affect students’ perceptions of our research topic, we changed a portion of our interviews to discuss national events in science, technology, engineering, and mathematics (STEM) classrooms and how students viewed these events in relation to engineering. We interviewed first-year undergraduate students (n = 12) who indicated large differences of attitudes towards diverse individuals, experiences with diverse team members, and/or residing at the intersection of multiple diversity markers. We asked participants during the Spring of 2017 to reflect on the personal impact of recent national events and how political discussions have or have not been integrated into their STEM classrooms. During interviews students were asked: 1) Have recent national events impacted you in any way? 2) Have national events been discussed in your STEM classes? 3) If so, what was discussed and how was it discussed? 4) Do these conversations have a place in STEM classes? 5) Are there events you wish were discussed that have not been? Inductive coding was used to analyze interviews and develop themes that were audited for quality by the author team. Two preliminary themes emerged from analysis: political awareness and future-self impact. Students expressed awareness of current political events at the local, national and global levels. They recognized personal and social impacts that these events imposed on close friends, family members, and society. However, students were unsure of how to interpret political dialogue as it relates to policy in engineering disciplines and practices. This uncertainty led students to question their future-selves or careers in engineering. As participants continued to discuss their uncertainty, they expressed a desire to make explicit connections between politics and STEM and their eventual careers in STEM. These findings suggest that depoliticization in the classroom results in engineering students having limited consciousness of how political issues are relevant to their field. This disconnect of political discourse in the classroom gives us a better understanding of how engineering students make sense of current national events in the face of depoliticization. By re-politicising STEM classrooms in a way relevant to students’ futures, educators can better utilize important dialogues to help students understand how their role as engineers influence society and how the experiences of society can influence their practice of engineering. 

   more » « less