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1. Understanding the ‘us all’ in Engineering 4 Us All through the Experiences of High School Teachers

   Berhane, B. ; Dalal, M. ; Klein-Gardner, S. ; Carberry, A. ; Reid, K. ; Beauchamp, C. ; Kouo, J. ; Pines, D. ( January 2021 , 3rd annual CoNECD – The Collaborative Network for Engineering and Computing Diversity Conference)

   null (Ed.)

   As our nation’s need for engineering professionals grows, a sharp rise in P-12 engineering education programs and related research has taken place (Brophy, Klein, Portsmore, & Rogers, 2008; Purzer, Strobel, & Cardella, 2014). The associated research has focused primarily on students’ perceptions and motivations, teachers’ beliefs and knowledge, and curricula and program success. The existing research has expanded our understanding of new K-12 engineering curriculum development and teacher professional development efforts, but empirical data remain scarce on how racial and ethnic diversity of student population influences teaching methods, course content, and overall teachers’ experiences. In particular, Hynes et al. (2017) note in their systematic review of P-12 research that little attention has been paid to teachers’ experiences with respect to racially and ethnically diverse engineering classrooms. The growing attention and resources being committed to diversity and inclusion issues (Lichtenstein, Chen, Smith, & Maldonado, 2014; McKenna, Dalal, Anderson, & Ta, 2018; NRC, 2009) underscore the importance of understanding teachers’ experiences with complementary research-based recommendations for how to implement engineering curricula in racially diverse schools to engage all students. Our work examines the experiences of three high school teachers as they teach an introductory engineering course in geographically and distinctly different racially diverse schools across the nation. The study is situated in the context of a new high school level engineering education initiative called Engineering for Us All (E4USA). The National Science Foundation (NSF) funded initiative was launched in 2018 as a partnership among five universities across the nation to ‘demystify’ engineering for high school students and teachers. The program aims to create an all-inclusive high school level engineering course(s), a professional development platform, and a learning community to support student pathways to higher education institutions. An introductory engineering course was developed and professional development was provided to nine high school teachers to instruct and assess engineering learning during the first year of the project. This study investigates participating teachers’ implementation of the course in high schools across the nation to understand the extent to which their experiences vary as a function of student demographic (race, ethnicity, socioeconomic status) and resource level of the school itself. Analysis of these experiences was undertaken using a collective case-study approach (Creswell, 2013) involving in-depth analysis of a limited number of cases “to focus on fewer "subjects," but more "variables" within each subject” (Campbell & Ahrens, 1998, p. 541). This study will document distinct experiences of high school teachers as they teach the E4USA curriculum. Participants were purposively sampled for the cases in order to gather an information-rich data set (Creswell, 2013). The study focuses on three of the nine teachers participating in the first cohort to implement the E4USA curriculum. Teachers were purposefully selected because of the demographic makeup of their students. The participating teachers teach in Arizona, Maryland and Tennessee with predominantly Hispanic, African-American, and Caucasian student bodies, respectively. To better understand similarities and differences among teaching experiences of these teachers, a rich data set is collected consisting of: 1) semi-structured interviews with teachers at multiple stages during the academic year, 2) reflective journal entries shared by the teachers, and 3) multiple observations of classrooms. The interview data will be analyzed with an inductive approach outlined by Miles, Huberman, and Saldaña (2014). All teachers’ interview transcripts will be coded together to identify common themes across participants. Participants’ reflections will be analyzed similarly, seeking to characterize their experiences. Observation notes will be used to triangulate the findings. Descriptions for each case will be written emphasizing the aspects that relate to the identified themes. Finally, we will look for commonalities and differences across cases. The results section will describe the cases at the individual participant level followed by a cross-case analysis. This study takes into consideration how high school teachers’ experiences could be an important tool to gain insight into engineering education problems at the P-12 level. Each case will provide insights into how student body diversity impacts teachers’ pedagogy and experiences. The cases illustrate “multiple truths” (Arghode, 2012) with regard to high school level engineering teaching and embody diversity from the perspective of high school teachers. We will highlight themes across cases in the context of frameworks that represent teacher experience conceptualizing race, ethnicity, and diversity of students. We will also present salient features from each case that connect to potential recommendations for advancing P-12 engineering education efforts. These findings will impact how diversity support is practiced at the high school level and will demonstrate specific novel curricular and pedagogical approaches in engineering education to advance P-12 mentoring efforts. 

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2. The Double Bind of Race and Gender: A Look into the Experiences of Women of Color in Engineering

   Cross, K ; Mendenhal, R ; Clancy, K.B.H. ; Amos, J.R. ( June 2017 , ASEE Annual Conference proceedings)

   African Americans, Latinos/Latinas, and other traditionally underserved ethnic/racial groups are needed for the next generation of engineers, scientists, and STEM educators. Women of color (WOC), in particular, represent a tremendous untapped human capital that could further provide a much-needed diversity of perspective essential to sustain technological advantages and to promote positive academic climate. Recently engineering educators have questioned the STEM community commitment towards increasing the participation of WOC. Indeed, national reports of domestic students studying and completing STEM degrees show marginal improvement in broadening participation with significant lag in engineering, despite the known benefits of diversity. Therefore, more must be done by the STEM community to attract and retain WOC. For students of color, campus climate issues around race, class, and gender are critical components shaping their higher education learning environment. Research suggests hostile campus climates are associated with students of color leaving STEM fields before graduating. Such barriers can be more pronounced for WOC who often experience a “double bind” of race and gender marginalization when navigating the STEM culture. Therefore, it is important that educators understand experiences of WOC and what is needed to improve students’ experiences in order to minimize the performance gap in key indicators (e.g., retention, achievement, and persistence). We seek to address this STEM need through the guiding research question: “How does the double bind of race and gender impact the experience of women of color in engineering?” The data reported here is part of a larger, sequential mixed-methods study that is informed by the Womanist and intersectionality theoretical frameworks. For the first time, we introduce the Womanist Identity Attitude scale to engineering education research, which provides an efficient way to understand gender and racial identity development of WOC along with the intersection of identities. Intersectionality provides a means to produce scholarship that investigates the connection between social identity dimensions and educational conditions. Social identity models that adhere to intersectionality concepts acknowledge that multiple oppressed identities have a cumulative, not additive, impact. Although intersectionality is used to understand the experiences of students of color in higher education, few engineering education studies apply an intersectionality framework, particularly for WOC. After a short pilot study, we anticipate the survey results will generate three outcomes. First, the survey results will show what intersecting identities most impact the experience of WOC in engineering. Second, interview question and potential themes will be created by grouping results into clusters of intersectionality types or exemplars of intersecting identities. Finally, we will generate strategies to overcome the challenge of the double bind for WOC in engineering by examining the context and scope of intersecting identities emphasized by participants in the survey to. Overall, the results presented here will provide the foundation for a larger study that will lead to a deeper understanding of the challenges WOC face in the engineering culture and expose areas to improve inclusion efforts that target WOC. 

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3. The Double Bind of Race and Gender: A Look into the Experiences of Women of Color in Engineering

   Cross, Kelly J. ; Clancy, Kathryn B.H. ; Mendenhall, Ruby ; Imoukhuede, Princess ; Amos, Jennifer R. ( June 2017 , Proceedings – American Society of Engineering Education Annual Conference & Exposition (ASEE), Columbus, OH. June 24-28, 2017)

   African Americans, Latinos/Latinas, and other traditionally underserved ethnic/racial groups are needed for the next generation of engineers, scientists, and STEM educators. Women of color (WOC), in particular, represent a tremendous untapped human capital that could further provide a much-needed diversity of perspective essential to sustain technological advantages and to promote positive academic climate. Recently engineering educators have questioned the STEM community commitment towards increasing the participation of WOC. Indeed, national reports of domestic students studying and completing STEM degrees show marginal improvement in broadening participation with significant lag in engineering, despite the known benefits of diversity. Therefore, more must be done by the STEM community to attract and retain WOC. For students of color, campus climate issues around race, class, and gender are critical components shaping their higher education learning environment. Research suggests hostile campus climates are associated with students of color leaving STEM fields before graduating. Such barriers can be more pronounced for WOC who often experience a “double bind” of race and gender marginalization when navigating the STEM culture. Therefore, it is important that educators understand experiences of WOC and what is needed to improve students’ experiences in order to minimize the performance gap in key indicators (e.g., retention, achievement, and persistence). We seek to address this STEM need through the guiding research question: “How does the double bind of race and gender impact the experience of women of color in engineering?” The data reported here is part of a larger, sequential mixed-methods study that is informed by the Womanist and intersectionality theoretical frameworks. For the first time, we introduce the Womanist Identity Attitude scale to engineering education research, which provides an efficient way to understand gender and racial identity development of WOC along with the intersection of identities. Intersectionality provides a means to produce scholarship that investigates the connection between social identity dimensions and educational conditions. Social identity models that adhere to intersectionality concepts acknowledge that multiple oppressed identities have a cumulative, not additive, impact. Although intersectionality is used to understand the experiences of students of color in higher education, few engineering education studies apply an intersectionality framework, particularly for WOC. After a short pilot study, we anticipate the survey results will generate three outcomes. First, the survey results will show what intersecting identities most impact the experience of WOC in engineering. Second, interview question and potential themes will be created by grouping results into clusters of intersectionality types or exemplars of intersecting identities. Finally, we will generate strategies to overcome the challenge of the double bind for WOC in engineering by examining the context and scope of intersecting identities emphasized by participants in the survey to. Overall, the results presented here will provide the foundation for a larger study that will lead to a deeper understanding of the challenges WOC face in the engineering culture and expose areas to improve inclusion efforts that target WOC. 

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4. Understanding the Professional Formation of Engineers through the Lens of Design Thinking: Unpacking theWicked Problem of Diversity and Inclusion

   Zoltowski, Carla B. ; Buzzanell, Patrice M. ; Brightman, Andrew O. ; Torres, David ; Eddington, Sean M. ( June 2017 , ASEE annual conference & exposition proceedings)

   Three broad issues have been identified in the professional formation of engineers: 1) the gap between what students learn in universities and what they practice upon graduation; 2) the limiting perception that engineering is solely technical, math, and theory oriented; and 3) the lack of diversity (representation of a wide range of people) and lack of inclusion (incorporation of different perspectives, values, and ways of thinking and being in engineering) in many engineering programs. These are not new challenges in engineering education, rather they are persistent and difficult to change. There have been countless calls to recruit and retain women and underrepresented minority group members into engineering careers and numerous strategies proposed to improve diversity, inclusion, and retention, as well as to calls to examine socio-technical integration in engineering cultures and education for professional formation. Despite the changes in some disciplinary profiles in engineering and the curricular reforms within engineering education, there still has not been the deep transformation needed to integrate inclusionary processes and thinking into professional formation. In part, the reason is that diversity and inclusion are still framed as simply “numbers problems” to be solved. What is needed instead is an approach that understands and explores diversity and inclusion as interrelated with the epistemological (what do engineers need to know) and ontological (what does it mean to be an engineer) underpinnings of engineering. These issues are highly complex, interconnected, and not amenable to simple solutions, that is, they are “wicked” problems. They require design thinking. Thus our NSF-funded Research in the Formation of Engineers (RFE) study utilizes a design thinking approach and research activities to explore foundational understandings of formation and diversity and inclusion in engineering while addressing the three project objectives: 1) Better prepare engineers for today’s workforce; 2) Broaden understandings of engineering practice as both social and technical; and 3) Create and sustain more diverse and inclusionary engineering programs. The project is organized around the three phases of the design process (inspiration, ideation, and implementation), and embedded within the design process is a longitudinal, multiphase, mixed-methods study. Although the goal is to eventually study these objectives on a broader scale, we begin with a smaller context: the School of Electrical and Computer Engineering (ECE) and the Weldon School of Biomedical Engineering (BME) at Purdue University. These schools share similarities with some common coursework and faculty, but also provide contrasts as BME’s undergraduate population, on average for recent semesters, has been 44-46% female, where ECE has been 13-14% female. Although BME has slightly more underrepresented minority students (7-8% versus 5%), approximately 60% of BME students are white, versus 40% for ECE. It is important to note that Purdue’s School of ECE offers B.S. degrees in Electrical Engineering (EE) and Computer Engineering (CmpE), which reflect unique disciplinary cultures. Additionally, the schools differ significantly on undergraduate enrollment. The BME enrollment was 278, whereas ECE’s enrollment was 675 in EE and 541 in CmpE1. In this paper we describe the background literature and the research design, including the study contexts, target subject populations, and procedures for quantitative and qualitative data collection and analysis. In addition, we present the data collected during the first phase of the research project. In our poster, we will present preliminary analysis of the first phase data. 

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5. A Review of Competency‐Based Learning: Tools, Assessments, and Recommendations

   https://doi.org/10.1002/jee.20180  

   Henri, Maria ; Johnson, Michael D. ; Nepal, Bimal ( November 2017 , Journal of Engineering Education)

   Over the past decade, there has been a shift in science, technology, engineering and math education, especially in engineering, towards a competency‐based pedagogy. Competency‐based learning (CBL) is an outcome‐based, student‐centered form of instruction where students progress to more advanced work upon mastering the necessary prerequisite content and skills. Many articles have been published on the implementation of CBL in engineering higher education; however, the literature lacks a systematic review that summarizes prior work to inform both future research and practice.

   The purpose of this review is to integrate previous literature as well as identify gaps in competency‐based engineering higher education research. It summarizes the different approaches for implementing CBL, the effects of the pedagogy on student outcomes, tools to enhance its effectiveness, and assessment strategies. In addition, suggestions and recommendations for future research are provided.

   Engineering education articles were obtained from several EBSCO educational databases. The search was limited to articles published from 2005‐2015, and inclusion criteria consisted of peer‐reviewed journal articles that address the use of CBL in engineering higher education. Articles were then classified into several categories, summarized, and evaluated.

   Theoretical and applied perspectives are provided that address both the theoretical basis for the effectiveness of CBL and practical aspects of implementing successful CBL instruction in engineering education. There are gaps in the literature regarding how CBL programs should be structured and assessed. Future research directions include empirical quantitative evaluation of CBL's pedagogical effectiveness and the use of CBL for teaching professional skills.

    

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