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1. Early Career Engineers’ Views of Ethics and Social Responsibility: Study Overview

   Claussen, S. ; Jesiek, B. K. ; Zoltowski, C. B. ; Howland, S. ( July 2021 , Proceedings of the 2021 American Society of Engineering Education Virtual Annual Conference)

   Amidst growing concerns about a lack of attention to ethics in engineering education and professional practice, a variety of formal course-based interventions and informal or extracurricular programs have been created to improve the social and ethical commitments of engineering graduates. To supplement the formal and informal ethics education received as undergraduate students, engineering professionals often also participate in workplace training and professional development activities on ethics, compliance, and related topics. Despite this preparation, there is growing evidence to suggest that technical professionals are often challenged to navigate ethical situations and dilemmas. Some prior research has focused on assessing the impacts of a variety of learning experiences on students’ understandings of ethics and social responsibility, including the PIs’ prior NSF-funded CCE STEM study which followed engineering students through the four years of their undergraduate studies using both quantitative and qualitative research methods. This prior project explored how the students’ views on these topics changed across demographic groups, over time, between institutions, and due to specific interventions. Yet, there has been little longitudinal research on how these views and perceptions change (or do not change) among engineers during the school-to-work transition. Furthermore, there has been little exploration of how these views aremore »influenced by the professional contexts in which these engineers work, including cultures and norms prevalent in different technical fields, organizations, and industry sectors. This NSF-supported Ethical and Responsible Research (ER2) study responds to these gaps in the literature by asking: RQ1) How do perceptions of ethics and social responsibility change in the transition from undergraduate engineering degree programs to the workplace (or graduate studies), and how are these perceptions shaped or influenced?, and RQ2) How do perceptions of ethics and social responsibility vary depending on a given individual’s engineering discipline/background and current professional setting? This paper gives an overview of the research project, describing in particular the longitudinal, mixed-methods study design which will involve collecting and analyzing data from a large sample of early career engineers. More specifically, we will present the proposed study contexts, timeline, target subject populations, and procedures for quantitative and qualitative data collection and analysis. We will also describe how this study leverages our prior project, thereby allowing unique longitudinal comparisons that span participants’ years as an engineering undergraduate student to their time as an early-career professional. Through this project, we aim to better understand how early career engineers’ perceptions of social and ethical responsibility are shaped by their prior experiences and current professional contexts. This paper will likely be of particular interest to scholars who teach or research engineering ethics, social responsibility, and professional practice.« less
2. Assessing Awareness and Competency of Engineering Freshmen on Ethical and Responsible Research and Practices

   1. Brahmbhatt*, P. ( June 2022 , Proceedings of the American Society for Engineering Education)

   This paper presents the initial work of a recently funded NSF project on ethical and responsible research and practices in science and engineering. The objective of this research is to improve instructor training, interventions, and student outcomes in high schools and universities to improve awareness and commitment to ethical practices in STEM coursework. The project will generate a robust snapshot of the ethical knowledge, reasoning skills, attitudes, and practices of several thousand undergraduate engineering students. This snapshot will inform the development of a three-week enrichment opportunity for high school STEM teachers. Working with university faculty and graduate students, these teachers will develop learning modules on ethical issues related to their courses. The snapshot will also identify gaps and guide the creation of targeted interventions that will be used in second-, third-, and fourth-year engineering courses. This data-driven project uses a mixed-methods approach to generate a better understanding of the impact of ethics interventions at various points in a student's academic development by developing and using a set of instruments to measure cognitive, affective, and behavioral aspects of ethical competency and self-efficacy. To that end, a second snapshot will be taken by testing and surveying engineering students in their capstone coursesmore »to provide a broad overview of the competence and self-confidence that engineering students have in dealing with ethical STEM issues, to determine the efficacy of various interventions, and to improve future interventions. Utilizing repeated measures and possessing a longitudinal dimension, the project will generate extensive data about the development of ethical competency, ethical self-efficacy, and their relationship. The interventions designed for secondary and tertiary classrooms will build on best practices for micro-insertion of ethics content that are practical and help students understand how technical competencies fit within broader social, economic, and environmental contexts. The capstone snapshot will also provide some measure of the impact of other experiences (e.g., undergraduate research, internships, service learning) and courses (e.g., humanities, social science, and business courses) on development of ethical practices. This report marks the start of a five-year project; therefore, the results presented in this paper represent findings from the engineering ethics literature and baseline results from survey of engineering freshmen at Texas A&M University. The findings from the survey are being utilized in developing intervention modules that will be integrated in upper-level engineering courses and training materials for high school teachers.« less
3. Encountering Engineering Ethics in the Workplace: Stories from the Trenches

   Kim, D. ; Howland, S. J. ; Jesiek, B. K. ( July 2021 , Proceedings of the 2021 American Society of Engineering Education Virtual Annual Conference)

   While formal coursework remains one of the most common strategies for developing ethics knowledge and competence among engineering students, ethical situations also surface in many other settings. In our own research on engineering student perceptions of ethics and social responsibility, we found that many engineering interns and co-ops reported encountering ethical issues or dilemmas in the workplace. To further illuminate such encounters, this paper aims to: 1) identify and describe real-world ethical issues encountered by engineering students in workplace settings, and 2) investigate what students learned from these experiences. We address these objectives by reporting select results from an ongoing qualitative analysis of 33 interviews with undergraduate students in their fourth year of college. We more specifically present a series of illustrative cases drawn from four of the interviews, selected because the participants described specific work situations in considerable detail and the cases represent a wide variety of ethical concerns. The purpose for sharing these cases is threefold. First, we note some specific lessons that our subjects learned (or failed to learn) through the selected cases. Second, we argue that the workplace is a particularly rich setting for learning about professional ethics. Third, we make recommendations for better scaffolding andmore »supporting student learning in workplace settings. We expect this paper will be of particular interest to engineering ethics scholars studying where and how students learn about ethics, instructors looking for ways to enhance and extend ethics learning, and students preparing for internship, co-op, and/or full-time job roles.« less
4. 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. Tomore »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.« less
5. Insights from the First Two Years of a Project Partnering Middle School Teachers with Industry to Bring Engineering to the Science Classroom

   Gillen, A. L. ; Grohs, J. R. ; Matusovich, H. M. ; Kirk, G. R. ; Lesko, H. L. ; Carrico, C. ( May 2019 , ASEE Annual Conference proceedings)

   Barriers to broadening participation in engineering to rural and Appalachian youth include misalignment with family and community values, lack of opportunities, and community misperceptions of engineering. While single interventions are unlikely to stimulate change in these areas, more sustainable interventions that are co-designed with local relevance appear promising. Through our NSF ITEST project, we test the waters of this intervention model through partnership with school systems and engineering industry to implement a series of engineering-themed, standards-aligned lessons for the middle school science classroom. Our mixed methods approach includes collection of interview and survey data from administrators, teachers, engineers, and university affiliates as well as observation and student data from the classroom. We have utilized theory from learning science and organizational collaboration to structure and inform our analysis and explore the impact of our project. The research is guided by the following 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’smore »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? In year one, we involved nine 6th grade teachers, three engineering companies, and over 500 students. In year two, we expanded to include 7th grade teachers in our partner schools and the new students moving up to 6th grade. Lessons aligned with students' everyday experiences and connected to industry. For example, students created bouncy balls and tested their effectiveness on materials produced from partner manufacturing facilities. From preliminary analysis of data collected in the first two years of the project (e.g, the Draw an Engineer Test and teacher interviews), we have begun to see evidence of positive student and teacher impact. Additionally, our application of collaborative theory to the investigation of stakeholder perceptions of the project has revealed implications for partnering with school systems and engineering industry. For example, key individuals at each organization may serve as important conduits for program communication and collaborative work.« less