Engineering is a social enterprise. A successful engineering career depends on how engineers manage their relationships with diverse stakeholders including managers, clients, contractors, and the p...

Global society is facing formidable current and future problems that threaten the prospects for justice and peace, sustainability, and the well-being of humanity both now and in the future. Many of these problems are related to science and technology and to how they function in the world. If the social responsibility of scientists and engineers implies a duty to safeguard or promote a peaceful, just and sustainable world society, then science and engineering education should empower students to fulfil this responsibility. (...) The contributions to this special issue present European examples of teaching social responsibility to students in science and engineering, and provide examples and discussion of how this teaching can be promoted, and of obstacles that are encountered. Speaking generally, education aimed at preparing future scientists and engineers for social responsibility is presently very limited and seemingly insufficient in view of the enormous ethical and social problems that are associated with current science and technology. Although many social, political and professional organisations have expressed the need for the provision of teaching for social responsibility, important and persistent barriers stand in the way of its sustained development. What is needed are both bottom-up teaching initiatives from individuals or groups of academic teachers, and top-down support to secure appropriate embedding in the university. Often the latter is lacking or inadequate. Educational policies at the national or international level, such as the Bologna agreements in Europe, can be an opportunity for introducing teaching for social responsibility. However, frequently no or only limited positive effect of such policies can be discerned. Existing accreditation and evaluation mechanisms do not guarantee appropriate attention to teaching for social responsibility, because, in their current form, they provide no guarantee that the curricula pay sufficient attention to teaching goals that are desirable for society as a whole. (shrink)

Discussions of ethics within in-service teacher education tend to focus on microethical concerns (e.g., discipline) that deal with decision making at interpersonal levels. Issues concerning educational technology are no exception. Yet, as teachers choose and are expected to integrate technological devices (e.g., laptops) and sociotechnical systems (e.g., learning management systems) into pedagogical practices, their classrooms and schools may become implicated in macroethical issues (e.g., electronic waste) that reach beyond the local consequences of their direct actions. Necessitated by tight couplings of (...) technology and education, this article presents the concept of macroethics for teacher educators by grounding it in three areas of concern: obsolescence, automation, and big data. These three areas offer opportunities to make economic and environmental issues more central to case studies on technology in teacher education. At the same time, teacher educators will need to put emphasis on critical reflection and collective action in units on macroethics since the limited impact of individual decision-making on these issues may put teachers in double binds (i.e., dilemmas with contradictory demands). (shrink)

Although undergraduate engineering ethics courses often include the development of moral sensitivity as a learning objective and the use of active learning techniques, teaching centers on the transmission of cognitive knowledge. This article describes a complementary assignment asking students to perform an ethics “experiment” on themselves that has a potential to enhance affective learning and moral imagination. The article argues that the focus on cognitive learning may not promote, and may even impair, our efforts to foster moral sensitivity. In contrast, (...) the active learning assignments and exercises, like the ethics “experiment” discussed, offer great potential to expand the scope of instruction in engineering ethics to include ethical behavior as well as knowledge. Engineering ethics education needs to extend beyond the narrow range of human action associated with the technical work of the engineer and explore ways to draw on broader lifeworld experiences to enrich professional practice and identity. (shrink)

Professionals in environmental fields engage with complex problems that involve stakeholders with different values, different forms of knowledge, and contentious decisions. There is increasing recognition of the need to train graduate students in interdisciplinary environmental science programs in these issues, which we refer to as “social ethics.” A literature review revealed topics and skills that should be included in such training, as well as potential challenges and barriers. From this review, we developed an online survey, which we administered to faculty (...) from 81 United States colleges and universities offering IESPs. Respondents overwhelmingly agreed that IESPs should address values in applying science to policy and management decisions. They also agreed that programs should engage students with issues related to norms of scientific practice. Agreement was slightly less strong that IESPs should train students in skills related to managing value conflicts among different stakeholders. The primary challenges to incorporating social ethics into the curriculum were related to the lack of materials and expertise for delivery, though challenges such as ethics being marginalized in relation to environmental science content were also prominent. Challenges related to students’ interest in ethics were considered less problematic. Respondents believed that social ethics are most effectively delivered when incorporated into existing courses, and they preferred case studies or problem-based learning for delivery. Student competence is generally not assessed, and respondents recognized a need for both curricular materials and assessment tools. (shrink)

One of the core problems with engineering ethics education is perceptual. Although ethics is meant to be a central component of today’s engineering curriculum, it is often perceived as a marginal requirement that must be fulfilled. In addition, there is a mismatch between faculty and student perceptions of ethics. While faculty aim to communicate the nuances and complexity of engineering ethics, students perceive ethics as laws, rules, and codes that must be memorized. This paper provides some historical context to better (...) understand these perceptual differences, and suggests that curriculum constraints are important contributing factors. Drawing on the growing scholarship of student engagement approaches to pedagogy, the paper explores how students can be empowered to effect change in the broader engineering curriculum through engineering ethics. The paper describes a student engagement approach to pedagogy that includes students as active participants in curriculum design—a role that enables them to critically reflect about why ethics is a requirement. Including students in the process of curriculum design leads students to reframe ethics as an integrative tool with the capacity to bring together different engineering departments and build bridges to non-engineering fields. This paper argues that students can and should play an active and important role in relocating ethics from the periphery to the core of the engineering curriculum. (shrink)

Emotions are often portrayed as subjective judgments that pose a threat to rationality and morality, but there is a growing literature across many disciplines that emphasizes the centrality of emotion to moral reasoning. For engineers, however, being rational usually means sequestering emotions that might bias analyses—good reasoning is tied to quantitative data, math, and science. This paper brings a new pedagogical perspective that strengthens the case for incorporating emotions into engineering ethics. Building on the widely established success of active and (...) collaborative learning environments, in particular the problem-based learning (PBL) philosophy and methodology, the paper articulates new strategies for incorporating emotion into engineering ethics education. An ethics education pilot study is analyzed to explore how PBL can engage students’ emotions. Evidence suggests that PBL empowers students to cultivate value for engineering ethics and social responsibility, and in doing so, redefine the societal role of the engineer. Taking students’ emotions seriously in engineering ethics offers an effective strategy to meaningfully engage students in ethical learning. (shrink)

Emotions are often portrayed as subjective judgments that pose a threat to rationality and morality, but there is a growing literature across many disciplines that emphasizes the centrality of emotion to moral reasoning. For engineers, however, being rational usually means sequestering emotions that might bias analyses—good reasoning is tied to quantitative data, math, and science. This paper brings a new pedagogical perspective that strengthens the case for incorporating emotions into engineering ethics. Building on the widely established success of active and (...) collaborative learning environments, in particular the problem-based learning philosophy and methodology, the paper articulates new strategies for incorporating emotion into engineering ethics education. An ethics education pilot study is analyzed to explore how PBL can engage students’ emotions. Evidence suggests that PBL empowers students to cultivate value for engineering ethics and social responsibility, and in doing so, redefine the societal role of the engineer. Taking students’ emotions seriously in engineering ethics offers an effective strategy to meaningfully engage students in ethical learning. (shrink)

The purpose of this paper is to diagnose and analyze the gap between philosophy of technology and engineering ethics and to suggest bridging them in a constructive way. In the first section, I will analyze why philosophy of technology and engineering ethics have taken separate paths so far. The following section will deal with the so-called macro-approach in engineering ethics. While appreciating the initiative, I will argue that there are still certain aspects in this approach that can be improved. In (...) the third, fourth, and fifth sections, I will point out three shortcomings of engineering ethics in terms of its macro-level discourse and argue that a number of certain insights taken from the study of philosophy of technology could be employed in overcoming those problems. In the concluding section, a final recommendation is made that topics of philosophy of technology be included in the curriculum of engineering ethics. (shrink)

Engineering programs in the United States have been experimenting with diverse pedagogical approaches to educate future professional engineers. However, a crucial dimension of ethics education that focuses on the values, personal commitments, and meaning of engineers has been missing in many of these pedagogical approaches. We argue that a value-based approach to professional ethics education is critically needed in engineering education, because such an approach is indispensable for cultivating self-reflective and socially engaged engineers. This paper starts by briefly comparing two (...) prevalent approaches to ethics education in science and engineering: professional and philosophical. While we acknowledge that both approaches help meet certain ethics education objectives, we also argue that neither of these is sufficient to personally engage students in authentic moral learning. We make the case that it is important to connect ethics education to the heart, which is extensively driven by values, and present a value-based approach to professional ethics education. We provide some classroom practices that cultivate a safe, diverse, and engaging learning environment. Finally, we discuss the implications of a value-based approach to professional ethics education for curriculum design and pedagogical practice, including opportunities and challenges for engineering faculty eager to incorporate value-based inquiry into their classrooms. (shrink)

In response to widespread policy prescriptions for responsible innovation, social scientists and engineering ethicists, among others, have sought to engage natural scientists and engineers at the ‘midstream’: building interdisciplinary collaborations to integrate social and ethical considerations with research and development processes. Two ‘laboratory engagement studies’ have explored how applying the framework of midstream modulation could enhance the reflections of natural scientists on the socio-ethical context of their work. The results of these interdisciplinary collaborations confirm the utility of midstream modulation in (...) encouraging both first- and second-order reflective learning. The potential for second-order reflective learning, in which underlying value systems become the object of reflection, is particularly significant with respect to addressing social responsibility in research practices. Midstream modulation served to render the socio-ethical context of research visible in the laboratory and helped enable research participants to more critically reflect on this broader context. While lab-based collaborations would benefit from being carried out in concert with activities at institutional and policy levels, midstream modulation could prove a valuable asset in the toolbox of interdisciplinary methods aimed at responsible innovation. (shrink)

Engineers should learn how to act on their responsibility to society during their education. At present, however, it is unknown what students think about the meaning of socially responsible engineering. This paper synthesizes 4 years of longitudinal interviews with engineering students as they progressed through college. The interviews revolved broadly around how students saw the connections between engineering and social responsibility, and what influenced these ideas. Using the Weidman Input–Environment–Output model as a framework, this research found that influences included required (...) classes such as engineering ethics, capstone design, and some technical courses, pre-college volunteering and familial values, co-curricular groups such as Engineers Without Borders and the Society of Women Engineers, as well as professional experiences through internships. Further, some experiences such as technical courses and engineering internships contributed to confine students’ understanding of an engineer’s social responsibility. Overall, students who stayed in engineering tended to converge on basic responsibilities such as safety and bettering society as a whole, but tended to become less concerned with improving the lives of the marginalized and disadvantaged. Company loyalty also became important for some students. These results have valuable, transferable contributions, providing guidance to foster students’ ideas on socially responsible engineering. (shrink)

Instituciones políticas como la Comisión Europea y el Gobierno de España han manifestadosu interés y predisposición para sentar las bases de una gobernanza ética de la Inteligencia Artificial (IA). En particular, han planteado el impulso de una Inteligencia Artificial confiable a través de unconjunto de directrices y estrategias. A pesar del beneficio que reportan estas iniciativas políticas, no es posible apreciar en su conjunto una estrategia educativa específica que contribuya a la generación de un ecosistema ético de IA fundamentado en (...) la confianza. En ese sentido, el objetivo principal de este trabajo consiste en explicar que la enseñanza de la ética aplicada en los estudios de ingeniería constituye una apuesta para el fortalecimiento profesional, la gobernanza ética yuna investigación e innovación responsables. Para alcanzar este objetivo, en primer lugar, serándetallados algunos de los aspectos esenciales que dotan de un valor significativo a la enseñanza de la ética aplicada, subrayando la responsabilidad social que presentan las universidades en este terreno. En segundo lugar, se mostrará una clasificación de las asignaturas de ética relacionadas con la ingeniería en el entorno de las universidades públicas españolas. Y, en tercer lugar, se ofrecerá un marco teórico enraizado en la ética discursiva, promoviendo una mirada cívica en el contexto educativo de las profesiones. (shrink)

The course Science, Technology, and Society is taken by about 500 engineering students each year at Bilkent University, Ankara. Aiming to complement the highly technical engineering programs, it deals with the ethical, social, cultural, political, economic, legal, environment and sustainability, health and safety, reliability dimensions of science, technology, and engineering in a multidisciplinary fashion. The teaching philosophy and experiences of the instructor are reviewed. Community research projects have been an important feature of the course. Analysis of teaching style based on (...) a multi-dimensional model is given. Results of outcome measurements performed for ABET assessment are provided. Challenges and solutions related to teaching a large class are discussed. (shrink)

Purpose – The purpose of this article is to provide a commentary to the conceptual article by Norberto Patrignani and Diane Whitehouse, The Clean Side of Slow Tech. This article explores what can be easily overlooked in Information Communication Technology : the uncomfortable truth relating to the production, use and disposal of modern communication technology. Design/methodology/approach – In it, the author picks up on the main ideas that were argued, specifically that there is a need to take a closer look (...) at the production, use and disposal of modern communication technology. Findings – Connecting resource production, use and disposal and its affect on climate change will require those who are in the position to make changes to come up with solutions that also consider values, beliefs and norms that lead to particular types of behaviour. Research limitations/implications – ICT has had an enormous impact on people’s lives. However, there has been primarily focus on its life-accelerating attributes. Slowing down the process of production may open up possibilities for sustainable ICT development. Practical implications – The commentary, combined with Patrignani and Whitehouse’s paper may provide a resource for those responsible in training future ICT professionals. Social implications – If today’s society, and this includes users and producers of ICT, intends to go beyond the mere rhetoric about sustainability, individuals will need to take on a new kind of responsibility that covers the entire life cycle of technology. Originality/value – This commentary is intended to provide an additional viewpoint to the topic of sustainable ICT production. (shrink)

Contemporary engineering education recognises the need for engineering ethics content in undergraduate programmes to extend beyond concepts that form the basis of professional codes to consider relationality and context of engineering practice. Yet there is debate on how this might be done, and we argue that the design and pedagogy for engineering ethics has to consider what and to whom ethics is taught in a particular context. Our interest is in the possibilities and challenges of pursuing the dual imperatives of (...) socialization and critique. Socialization involves creating opportunities for all, in a diverse cohort of students, to access and engage with the dominant professional engineering ethics knowledge, while critique involves engaging with a range of ways of knowing, valuing, being and using language as relevant in contemporary engineering practice. We identify conceptual tools from engineering ethics and ethical pedagogy in education scholarship for our context. We illustrate how we use these tools systematically to strengthen our reflective practice in a first-year university engineering ethics module to a deeper form of reflexivity. Specifically, we explore the ways in which we attend to the dual imperatives and also highlight opportunities that we miss. We identify as key opportunities design choices such as how we formulated questions and prompts, and how we attended to content, context and language in selecting classroom texts. Other key opportunities were pedagogical choices of when and how to use student contributions in discussion, and what was made explicit in the classroom and assessment. We share our plans to take our learnings forward in our practice and consider the generative possibilities of these learnings and the concepts in other contexts. (shrink)

Hurricane Katrina was one of the worst disasters in United States history. Failures within New Orleans’ engineered hurricane protection system (levees and floodwalls) contributed to the severity of the event and have drawn considerable public attention. In the time since Katrina, forensic investigations have uncovered a range of issues and problems related to the engineering work. In this article, my goal is to distill from these investigations, and the related literature that has accumulated, some overarching macro-ethical issues that are relevant (...) for all engineers. I attempt to frame these issues, using illustrative examples taken from Katrina, in a way that might be of pedagogical use and benefit for engineering educators interested in engaging their students in discussions of engineering ethics, societal impact of engineered systems, engineering design, or related topics. Some of the issues discussed are problems of unanticipated failure modes, faulty assumptions, lack or misuse of information, the importance of resiliency, the effects of time, balancing competing interests, attending to the details of interfaces, the fickleness of risk perception, and how the past constrains the present. (shrink)

Engineering is a practice that must function in an environment of incomplete and uncertain knowledge. This environment has become even more difficult in an increasingly complex world. Engineering ethics has to be framed and taught in a way that addresses these realities. This paper proposes a combination of the philosophy of pragmatism and the ethic of care as a possible framework for the practice of engineering ethics that can provide flexibility and openness to address engineering ethics problems more realistically within (...) the ethos and culture of engineering. Embedding values into practice, pragmatism and care provide a broad, reflective, and corrective framework for engineering ethics that can accommodate the realities in which engineering operates. It is shown that these two approaches are more consonant with design methodologies and have a natural fit with design thinking, so they mesh well with what engineers do and with the complexities of their work today. As humans more and more try to alter the socio-techno-natural world, e.g., the earth’s climate, the combination of pragmatism and care will allow enhanced ethical behavior. Alterations to complex adaptive systems will produce highly uncertain results that require engineers to have a mindset that allows them to act with humility in the face of significant uncertainty and potential catastrophic failures. (shrink)

This article identifies limitations in traditional approaches to engineering ethics pedagogy, reflected in an overreliance on disaster case studies. Researchers in the field have pointed out that these approaches tend to occlude ethically significant aspects of day-to-day engineering practice and thus reductively individualize and decontextualize ethical decision-making. Some have proposed, as a remedy for these defects, the use of research and theory from Science and Technology Studies to enrich our understanding of the ways in which technology and engineering practice are (...) intricated in social and institutional contexts. While endorsing this approach, this article also argues that STS scholarship may not sufficiently address the kinds of questions about normativity and agency that are essential to engineering ethics. It proposes making use of the growing body of research in a field called “postphenomenology,” an approach that combines STS research with the traditional phenomenological concern with the standpoint of lived-experience. Postphenomenology offers a method of inquiry that combines STS’s investigation into social and institutional dimensions of technology with phenomenological reflection on our lived experience of embodied engagement with technical objects and sociotechnical systems, particularly the ways in which these involvements affect our moral perception and agency. The aim in using this approach in engineering ethics is thus to illuminate moral dimensions of everyday professional life of which practitioners may not typically be aware. The article concludes with some concrete curricular interventions for engineering ethics classrooms. (shrink)

In this paper, I make a novel case for an expansive approach to engineering ethics education, one that regards micro-ethics and macro-ethics as essentially complementary. Although others have voiced support for including macro-ethical reflection within engineering ethics education, I advance a stronger claim, arguing that isolating engineering ethics from macro-level issues risks rendering even micro-ethical inquiry morally meaningless. I divide my proposal into four parts. First, I clarify the distinction between micro-ethics and macro-ethics as I am construing it, defending my (...) characterization against a potential worry. Second, I consider but reject some arguments for a restrictive approach, one that excludes macro-ethical reflection from engineering ethics education. Third, I offer my central argument for an expansive approach. Finally, I suggest that macro-ethics education can learn something valuable from micro-ethics pedagogy. On my proposal, students consider both micro- and macro-ethical problems from the deliberative perspective, situating micro-ethical problems within a broader social framework but also situating macro-ethical problems within an engaged, practical framework. By emphasizing the value of the deliberative perspective, my proposal contributes to a growing call to broaden the scope of engineering ethics education while maintaining its practical relevance. (shrink)

This paper aims to review the empirical and theoretical research on engineering ethics education, by focusing on the challenges reported in the literature. The analysis is conducted at four levels of the engineering education system. First, the individual level is dedicated to findings about teaching practices reported by instructors. Second, the institutional level brings together findings about the implementation and presence of ethics within engineering programmes. Third, the level of policy situates findings about engineering ethics education in the context of (...) accreditation. Finally, there is the level of the culture of engineering education. The multi-level analysis allows us to address some of the limitations of higher education research which tends to focus on individual actors such as instructors or remains focused on the levels of policy and practice without examining the deeper levels of paradigm and purpose guiding them. Our approach links some of the challenges of engineering ethics education with wider debates about its guiding paradigms. The main contribution of the paper is to situate the analysis of the theoretical and empirical findings reported in the literature on engineering ethics education in the context of broader discussions about the purpose of engineering education and the aims of reform programmes. We conclude by putting forward a series of recommendations for a socio-technical oriented reform of engineering education for ethics. (shrink)

The article examines and extends work bringing together engineering ethics and Science and Technology Studies, which had built upon Diane Vaughan’s analysis of the Challenger shuttle accident as a test case. Reconsidering the use of her term “normalization of deviance,” the article argues for a middle path between moralizing against and excusing away engineering practices contributing to engineering disaster. To explore an illustrative pedagogical case and to suggest avenues for constructive research developing this middle path, it examines the emergence of (...) green chemistry and green engineering. Green chemistry began when Paul Anastas and John Warner developed a set of new rules for chemical synthesis that sought to learn from missed opportunities to avoid environmental damage in the twentieth century, an approach that was soon extended to engineering as well. Examination of tacit assumptions about historical counterfactuals in recent, interdisciplinary discussions of green chemistry illuminate competing views about the field’s prospects. An integrated perspective is sought, addressing how both technical practice within chemistry and engineering and the influence of a wider “social movement” can play a role in remedying environmental problems. (shrink)

This paper explores how undergraduate students understood the social relevance of their engineering course content knowledge and drew broader social and ethical implications from that knowledge. Based on a three-year qualitative study in a junior-level engineering class, we found that students had difficulty in acknowledging the social and ethical aspects of engineering as relevant topics in their coursework. Many students considered the immediate technical usability or improved efficiency of technical innovations as the noteworthy social and ethical implications of engineering. Findings (...) suggest that highly-structured engineering programs leave little room for undergraduate students to explore the ethical dimension of engineering content knowledge and interact with other students/programs on campus to expand their “technically-minded” perspective. We discussed the issues of the “culture of disengagement” :42–72, 2014) fueled by disciplinary elitism, spatial distance, and insulated curriculum prevalent in the current structure of engineering programs. We called for more conscious effort by engineering educators to offer meaningful interdisciplinary engagement opportunities and in-class conversations on ethics that support engineering students' holistic intellectual growth and well-rounded professional ethics. (shrink)

Engineering ethics education is a complex field characterized by dynamic topics and diverse students, which results in significant challenges for engineering ethics educators. The purpose of this paper is to introduce a systematic approach to determine what to teach and how to teach in an ethics curriculum. This is a topic that has not been adequately addressed in the engineering ethics literature. This systematic approach provides a method to: (1) develop a context-specific engineering ethics curriculum using the Delphi technique, a (...) process-driven research method; and (2) identify appropriate delivery strategies and instructional strategies using an instructional design model. This approach considers the context-specific needs of different engineering disciplines in ethics education and leverages the collaboration of engineering professors, practicing engineers, engineering graduate students, ethics scholars, and instructional design experts. The proposed approach is most suitable for a department, a discipline/field or a professional society. The approach helps to enhance learning outcomes and to facilitate ethics education curriculum development as part of the regular engineering curriculum. (shrink)

Many blame politicians, governments, and markets for the technically-driven problems the world faces. But why is it that there are almost always engineers and corporations willing to design and build the technologies that cause those problems, many times in spite of knowing about the negative consequences of those technologies? I offer in this paper practical guidance on how to engage in activist engineering, the goal of which is to get engineers to step back from their work and be able to (...) ask and have a conversation about the question, “What is the real problem, and does this problem ‘require’ an engineering solution?” Building on research in the history and philosophy of engineering, and engineering ethics and education, as well as current events—all of which highlight important issues of debate within engineering practice—I provide a list of questions that engineers can start with for self-reflection to better understand their motivations for doing engineering work, and to better understand the implications of their work. The questions relate to considerations engineers must make regarding the social, environmental, economic, and peace implications of their work, and relate to alternative and non-technical interventions to the problem at hand. I believe that each engineer should, in the end, be able to answer the questions: Why am I an engineer? For whose benefit do I work? What is the full measure of my moral and social responsibility? (shrink)

Promoting the ethical formation of engineering students through the cultivation of their discipline-specific knowledge, sensitivity, imagination, and reasoning skills has become a goal for many engineering education programs throughout the United States. However, there is neither a consensus throughout the engineering education community regarding which strategies are most effective towards which ends, nor which ends are most important. This study provides an overview of engineering ethics interventions within the U.S. through the systematic analysis of articles that featured ethical interventions in (...) engineering, published in select peer-reviewed journals, and published between 2000 and 2015. As a core criterion, each journal article reviewed must have provided an overview of the course as well as how the authors evaluated course-learning goals. In sum, 26 articles were analyzed with a coding scheme that included 56 binary items. The results indicate that the most common methods for integrating ethics into engineering involved exposing students to codes/standards, utilizing case studies, and discussion activities. Nearly half of the articles had students engage with ethical heuristics or philosophical ethics. Following the presentation of the results, this study describes in detail four articles to highlight less common but intriguing pedagogical methods and evaluation techniques. The findings indicate that there is limited empirical work on ethics education within engineering across the United States. Furthermore, due to the large variation in goals, approaches, and evaluation methods described across interventions, this study does not detail “best” practices for integrating ethics into engineering. The science and engineering education community should continue exploring the relative merits of different approaches to ethics education in engineering. (shrink)

Engineering ethics is a required aspect of accredited ABET programs, but there is widespread variation in how ethics is taught, to what ends, and how those ends are assessed. This variation makes it challenging to identify practices for teaching ethics to engineers aligned with extant practices in the field. In this study, we revise a recent coding framework by reviewing exemplary engineering ethics programs recognized by the National Academy of Engineering in 2016, or what we refer to as “exemplars.” We (...) pursue two primary objectives: (1) To apply and revise a prior coding framework to codify ethics learning objectives, instructional strategies, and assessment strategies in engineering education; and (2) To use the revised coding framework to identify trends in learning objectives, instructional strategies, and assessment strategies of NAE exemplars. We employ systemic review procedures to update the coding framework using 24 of 25 exemplars as a data source. The updated framework includes four primary categories associated with learning objectives, instructional strategies, assessment data collection strategies, and assessment design characteristics. Results indicate that ethical sensitivity or awareness was present in every exemplar as a learning objective, often alongside ethical reasoning-based learning objectives and the formation of professional skills. Exemplars employed numerous instructional strategies in tandem, as we coded eight out of 18 instructional strategies among at least half of the exemplars. Assignments/homework and summative reflections were the most oft-used sources of assessment data. Due to our challenges in coding assessment approaches, we offer practical suggestions for assessing engineering ethics instruction which are based on many of our coding discussions. We hope that this coding framework, the results classifying exemplary features of the NAE programs, and our practical suggestions can guide future instructors as they design, classify, assess, and report their approaches to engineering ethics education. (shrink)

Risk management is certainly one of the most important professional responsibilities of an engineer. As such, this activity needs to be combined with complex ethical reflections, and this requirement should therefore be explicitly integrated in engineering education. In this article, we analyse how this nexus between ethics and risk management is expressed in the engineering education research literature. It was done by reviewing 135 articles published between 1980 and March 1, 2016. These articles have been selected from 21 major journals (...) that specialize in engineering education, engineering ethics and ethics education. Our review suggests that risk management is mostly used as an anecdote or an example when addressing ethics issues in engineering education. Further, it is perceived as an ethical duty or requirement, achieved through rational and technical methods. However, a small number of publications do offer some critical analyses of ethics education in engineering and their implications for ethical risk and safety management. Therefore, we argue in this article that the link between risk management and ethics should be further developed in engineering education in order to promote the progressive change toward more socially and environmentally responsible engineering practices. Several research trends and issues are also identified and discussed in order to support the engineering education community in this project. (shrink)

Purpose This short viewpoint is a response to a lead paper on professional ethics in the information age. This paper aims to draw upon the authors’ experience of professional bodies such as the ACM over many years. Points of agreement and disagreement are highlighted with the aim of promoting wider debate. Design/methodology/approach An analysis of the lead paper is undertaken using a binary agree/disagree approach. This highlights the conflicting views which can then be considered in more detail. Findings Four major (...) agreements and four major disagreements are identified. There is an emphasis on “acultural” professionalism to promote moral behavior rather than amoral behavior. Originality/value This is an original viewpoint which draws from the authors’ practical experience and expertise. (shrink)

Institutions create their own internal cultures, including the culture of ethics that pervades scientific research, academic policy, and administrative philosophy. This paper addresses some of the issues involved in institutional enhancement of its culture of research ethics, focused on individual empowerment and strategies that individuals can use to initiate institutional change.

One of the core problems with engineering ethics education is perceptual. Although ethics is meant to be a central component of today’s engineering curriculum, it is often perceived as a marginal requirement that must be fulfilled. In addition, there is a mismatch between faculty and student perceptions of ethics. While faculty aim to communicate the nuances and complexity of engineering ethics, students perceive ethics as laws, rules, and codes that must be memorized. This paper provides some historical context to better (...) understand these perceptual differences, and suggests that curriculum constraints are important contributing factors. Drawing on the growing scholarship of student engagement approaches to pedagogy, the paper explores how students can be empowered to effect change in the broader engineering curriculum through engineering ethics. The paper describes a student engagement approach to pedagogy that includes students as active participants in curriculum design—a role that enables them to critically reflect about why ethics is a requirement. Including students in the process of curriculum design leads students to reframe ethics as an integrative tool with the capacity to bring together different engineering departments and build bridges to non-engineering fields. This paper argues that students can and should play an active and important role in relocating ethics from the periphery to the core of the engineering curriculum. (shrink)

Professionals in environmental fields engage with complex problems that involve stakeholders with different values, different forms of knowledge, and contentious decisions. There is increasing recognition of the need to train graduate students in interdisciplinary environmental science programs in these issues, which we refer to as “social ethics.” A literature review revealed topics and skills that should be included in such training, as well as potential challenges and barriers. From this review, we developed an online survey, which we administered to faculty (...) from 81 United States colleges and universities offering IESPs. Respondents overwhelmingly agreed that IESPs should address values in applying science to policy and management decisions. They also agreed that programs should engage students with issues related to norms of scientific practice. Agreement was slightly less strong that IESPs should train students in skills related to managing value conflicts among different stakeholders. The primary challenges to incorporating social ethics into the curriculum were related to the lack of materials and expertise for delivery, though challenges such as ethics being marginalized in relation to environmental science content were also prominent. Challenges related to students’ interest in ethics were considered less problematic. Respondents believed that social ethics are most effectively delivered when incorporated into existing courses, and they preferred case studies or problem-based learning for delivery. Student competence is generally not assessed, and respondents recognized a need for both curricular materials and assessment tools. (shrink)

In this paper, we discuss the use of role plays in ethics education for engineering students. After presenting a rough taxonomy of different objectives, we illustrate how role plays can be used to broaden students’ perspectives. We do this on the basis of our experiences with a newly developed role play about a Dutch political controversy concerning pig transport. The role play is special in that the discussion is about setting up an institutional framework for responsible action that goes beyond (...) individual action. In that sense, the role play serves a double purpose. It not only aims at teaching students to become aware of the different dimensions in decision making, it also encourages students to think about what such an institutional framework for responsible action might possibly look like. (shrink)

The Nanosilver Linings role play case offers participants first-person experience with interpersonal interaction in the context of the wicked problems of emerging technology macroethics. In the fictional scenario, diverse societal stakeholders convene at a town hall meeting to consider whether a nanotechnology-enabled food packaging industry should be offered incentives to establish an operation in their economically struggling Midwestern city. This original creative work was built with a combination of elements, selected for their established pedagogical efficacy and as topical dimensions of (...) the realistic scenario. The product life cycle is used as a framework for integrated consideration of scientific, societal, and ethical issues. The Nanosilver Linings hypothetical case was delivered through the format of the 3-hour workshop Ethics when Biocomplexity meets Human Complexity, providing an immersive, holistic ethics learning experience for STEM graduate students. Through their participation in the Nanosilver Linings case and Ethics when Biocomplexity meets Human Complexity workshop, four cohorts of science and engineering doctoral students reported the achievement of specific learning objectives pertaining to a range of macroethics concepts and professional practices, including stakeholder perspectives, communication, human values, and ethical frameworks. Automated text analysis of workshop transcripts revealed differences in sentiment and in ethical framework preference between societal stakeholder roles. These resources have been recognized as ethics education exemplars by the U.S. National Academy of Engineering. (shrink)

There has been increasing interest in developing practical, non-theoretical tools for analyzing ethical problems in public health, biomedicine, and other scientific disciplines so that professionals can make and justify ethical decisions in their own research or practice. Tools for ethical decisionmaking, together with case studies on ethics, are often used in graduate education programs and in continuing professional education. Students can benefit from opportunities to further develop their analytical skills, to recognize ethical issues, and to develop their moral sensitivity. One (...) practical approach for illustrating and facilitating ethical analysis uses cases with contrary facts and circumstances, an approach which complements rather than replaces theoretical approaches to moral reasoning. Cases with contrary facts and circumstances are presented in two or more alternative ways so that the facts, circumstances, or framing of one version runs counter to that of the other version (s). Cases with contrary facts, together with practical steps for identifying and analyzing ethical issues, are likely to be useful tools for illustrating and facilitating ethics analysis and stimulating the moral imagination. (shrink)

There is a widespread approach to the teaching of ethics to engineering students in which the exclusive focus is on engineers as individual agents and the broader context in which they do their work is ignored. Although this approach has frequently been criticised in the literature, it persists on a wide scale, as can be inferred from accounts in the educational literature and from the contents of widely used textbooks in engineering ethics. In this contribution we intend to: (1) Restate (...) why the individualistic approach to the teaching of ethics to engineering students is inadequate in view of preparing them for ethical, professional and social responsibility; (2) Examine the existing literature regarding the possible contribution of Science, Technology and Society (STS) scholarship in addressing the inadequacies of the individualistic approach; and (3) Assess this possible contribution of STS in order to realise desired learning outcomes regarding the preparation of students for ethical and social responsibility. (shrink)

To develop more effective ethics education for cross-cultural and international engineering, a study was conducted to determine what Chinese engineering students have learned and think about ethics. Recent research shows traditional approaches to ethics education are potentially ineffective, but also points towards ways of improving ethical behaviors. China is the world’s most populous country, graduating and employing the highest number of STEM majors, although little empirical research exists about the ethical knowledge and perspectives of Chinese engineering students. When compared to (...) engineering students in the US, Chinese engineering students received less ethics education; the form of the education they did receive stressed virtue ethics or the development of moral character; conceive of ethics in contradistinction to the law, where ethics deals with matters of right and wrong not covered by legality. Based on these findings and research in moral psychology and behavioral ethics, recommendations are made for improving engineering ethics education both in China and abroad. (shrink)

Ethics education has become essential in modern engineering. Ethics education in engineering has been increasingly implemented worldwide. It can improve ethical behaviors in technology and engineering design under the guidance of the philosophy of technology. Hence, this study aims to compare China-US engineering ethics education in Sino-Western philosophies of technology by using literature studies, online surveys, observational researches, textual analyses, and comparative methods. In my original theoretical framework and model of input and output for education, six primary variables emerge in (...) the pedagogy: disciplinary statuses, educational goals, instructional contents, didactic models, teaching methods, and edificatory effects. I focus on the similarities and differences of engineering ethics educations between China and the US in Chinese and Western philosophies of technology. In the field of engineering, the US tends toward applied ethics training, whereas China inclines toward practical moral education. The US is the leader, particularly in the amount of money invested and engineering results. China has quickened its pace, focusing specifically on engineering labor input and output. Engineering ethics is a multiplayer game effected at various levels among lower level technicians and engineers, engineering associations, and stockholders; middle ranking engineering ethics education, the ministry of education, the academy of engineering, and the philosophy of technology; and top national and international technological policies. I propose that professional engineering ethics education can play many important roles in reforming engineering social responsibility by international cooperation in societies that are becoming increasingly reliant on engineered devices and systems. Significantly, my proposals contribute to improving engineering ethics education and better-solving engineering ethics issues, thereby maximizing engineering sustainability. (shrink)

Research on the effectiveness of case studies in teaching engineering ethics in higher education is underdeveloped. To add to our knowledge, we have systematically compared the outcomes of two case approaches to an undergraduate course on the ethics of technology: a detached approach using real-life cases and a challenge-based learning approach with students and stakeholders acting as co-creators. We first developed a practical typology of case-study approaches and subsequently tested an evaluation method to assess the students’ learning experiences and outcomes (...) and staff interpretations and operationalizations, seeking to answer three questions: Do students in the CBL approach report higher basic needs, motivation and competence development compared to their peers in the detached approach? What is the relationship between student-perceived co-creation and their basic needs, motivation and competence development? And what are the implications of CBL/CC for engineering-ethics teaching and learning? Our mixed methods analysis favored CBL as it best supported teaching and research goals while satisfying the students’ basic needs and promoting intrinsic motivation and communication competences. Competence progress in other areas did not differ between approaches, and motivation in terms of identified regulation was lower for CBL, with staff perceiving a higher workload. We propose that our case typology model is useful and that as a method to engage students as co-creators, CBL certainly merits further development and evaluation, as does our effectiveness analysis for engineering ethics instruction in general and for case-study approaches in particular. (shrink)

Data science skills are rapidly becoming a necessity in modern science. In response to this need, institutions and organizations around the world are developing research data science curricula to teach the programming and computational skills that are needed to build and maintain data infrastructures and maximize the use of available data. To date, however, few of these courses have included an explicit ethics component, and developing such components can be challenging. This paper describes a novel approach to teaching data ethics (...) on short courses developed for the CODATA-RDA Schools for Research Data Science. The ethics content of these schools is centred on the concept of open and responsible science citizenship that draws on virtue ethics to promote ethics of practice. Despite having little formal teaching time, this concept of citizenship is made central to the course by distributing ethics content across technical modules. Ethics instruction consists of a wide range of techniques, including stand-alone lectures, group discussions and mini-exercises linked to technical modules. This multi-level approach enables students to develop an understanding both of “responsible and open science citizenship”, and of how such responsibilities are implemented in daily research practices within their home environment. This approach successfully locates ethics within daily data science practice, and allows students to see how small actions build into larger ethical concerns. This emphasises that ethics are not something “removed from daily research” or the remit of data generators/end users, but rather are a vital concern for all data scientists. (shrink)

Helping scientists and engineers challenge received assumptions about how science, engineering, and society relate is a critical cornerstone for macroethics education. Scientific and engineering research are frequently framed as first steps of a value-free linear model that inexorably leads to societal benefit. Social studies of science and assessments of scientific and engineering research speak to the need for a more critical approach to the noble intentions underlying these assumptions. “Science Outside the Lab” is a program designed to help early-career scientists (...) and engineers understand the complexities of science and engineering policy. Assessment of the program entailed a pre-, post-, and 1 year follow up survey to gauge student perspectives on relationships between science and society, as well as a pre–post concept map exercise to elicit student conceptualizations of science policy. Students leave Science Outside the Lab with greater humility about the role of scientific expertise in science and engineering policy; greater skepticism toward linear notions of scientific advances benefiting society; a deeper, more nuanced understanding of the actors involved in shaping science policy; and a continued appreciation of the contributions of science and engineering to society. The study presents an efficacious program that helps scientists and engineers make inroads into macroethical debates, reframe the ways in which they think about values of science and engineering in society, and more thoughtfully engage with critical mediators of science and society relationships: policy makers and policy processes. (shrink)

We believe that the professional responsibility of bioscience and biotechnology professionals includes a social responsibility to contribute to the resolution of ethically fraught policy problems generated by their work. It follows that educators have a professional responsibility to prepare future professionals to discharge this responsibility. This essay discusses two pilot projects in ethics pedagogy focused on particularly challenging policy problems, which we call “fractious problems”. The projects aimed to advance future professionals’ acquisition of “fractious problem navigational” skills, a set of (...) skills designed to enable broad and deep understanding of fractious problems and the design of good policy resolutions for them. A secondary objective was to enhance future professionals’ motivation to apply these skills to help their communities resolve these problems. The projects employed “problem based learning” courses to advance these learning objectives. A new assessment instrument, “Skills for Science/Engineering Ethics Test”, was designed and administered to measure the success of the courses in doing so. This essay first discusses the rationale for the pilot projects, and then describes the design of the pilot courses and presents the results of our assessment using SkillSET in the first pilot project and the revised SkillSET 2.0 in the second pilot project. The essay concludes with discussion of observations and results. (shrink)

This paper focuses on the question of What kind of engineering ethics (EE) is needed to develop holistic engineers who can practice and promote the principles of sustainable development? -/- It is argued that, given the existence of other models, an approach to EE, as argued for at EESD 2016, centred on “training engineers for handling ethical dilemmas in sustainability contexts” (Lundqvist and Svanstrom 2016) is inadequate to address the sustainability challenge facing engineers.. We contend that while EE is now (...) a diverse and fragmented field sociological tools can be used to understand this diversity. A framework is offered for understanding different approaches. This is used as the basis for arguing for a more extended and broad approach which allows us to focus on the relationship between social structure and human action and the need for “adequate social institutions and structures” (Becker 2012: 28) to enable ethical action. Thus engineers not should only understand the constraints and enablers emanating from the environments in which they work but can also strive for change in these environments. (shrink)