This paper explores the often-overlooked role of teaching assistants (TAs) in engineering ethics courses, and a particular challenge that TAs face in these roles. TAs not only undertake tasks like instructors, which include teaching, guiding, and evaluating courses, but they also assume the roles of “intermediaries between instructors and students” and “learners becoming teachers.” These distinct roles present TAs with unique challenges, one of which we call the neutrality problem. This problem pertains to whether TAs can (...) and should maintain a neutral stance in the classroom, particularly when students articulate ideas that deviate from the values promoted in the course or held by the TAs. Using a real-life teaching experience as illustrative, we claim that it is challenging and, at times, undesirable for TAs to achieve pedagogical neutrality, primarily due to their pre-existing understanding of ethics and the actual situation of the students. Nevertheless, we posit that TAs should strive to foster an environment where students are encouraged to improve their ethical awareness. Through the underrepresented lens of TAs, we aim to initiate a multi-faceted dialogue on the teaching philosophy and goal of engineering ethics. (shrink)

A joint effort by the University of California at Berkeley and Delft University of Technology to develop a graduate engineering ethics course for PhD students encountered two types of challenges: academic and institutional. Academically, long-term collaborative research efforts between engineering and philosophy faculty members might be needed before successful engineering ethics courses can be initiated; the teaching of ethics to engineering graduate students and collaborative research need to go hand-in-hand. Institutionally, both bottom-up (...) approaches at the level of the faculty and as a joint research and teaching effort, and top-down approaches that include recognition by a University’s administration and the top level of education management, are needed for successful and sustainable efforts to teach engineering ethics. (shrink)

This article describes the development and teaching of a course on global engineering ethics in Shanghai Jiao Tong University, China. It outlines course objectives, methods, and contents, and instructor experience and plans for future development. This is done with the goal of helping educators to plan standalone courses and/or integrated modules on global engineering and technology ethics, which address challenges arising from the increasingly cross-cultural and international environments of contemporary technology and engineering practice. These (...) efforts are motivated by the global environments of engineering, as well as recent research in empirical moral psychology. Although this course was developed and taught in China, as a course on global engineering ethics taught to students from throughout the world, its approach could be beneficial elsewhere. (shrink)

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The use of role-playing (“active learning”) as a teaching tool has been reported in areas as diverse as social psychology, history and analytical chemistry. Its use as a tool in the teaching of engineering ethics and professionalism is also not new, but the approach develops new perspectives when used in a college class of exceptionally wide cultural diversity. York University is a large urban university (40,000 undergraduates) that draws its enrolment primarily from the Greater Toronto Area, arguably one (...) of the most culturally diverse cities in the world, embracing the largest percentage of Canada’s immigration. Among the area’s five million inhabitants, 50% identify themselves as a visible minority born outside Canada, while over 100 languages and dialects are spoken daily. Although students admitted from this international pool have usually been exposed to western attitudes during secondary education and are rapidly assimilated into Canadian culture, responses to specific ethical issues are strongly influenced by their prior culture. Two and three-part scripts for case studies based on NSF or original scenarios were written to illustrate issues such as gifts, attitudes towards women and ethnic minorities, conflict of interest, whistle-blowing, sexual harassment, individual rights, privacy, environment, intellectual property, and others. Following the presentation, the actors lead group discussion based on previously specified questions. Once the initial shyness and reluctance of some cultures has been overcome through the building of rapport, students have written original scripts based on hypothetical or prior personal situations. The method is now being adopted in a short course format to assist the professional integration of foreign trained engineers. (shrink)

This article evaluates a family of criticism of how engineering ethics is now generally taught. The short version of the criticism might be put this way: Teachers of engineering ethics devote too much time to individual decisions and not enough time to social context. There are at least six version of this criticism, each corresponding to a specific subject omitted. Teachers of engineering ethics do not (it is said) teach enough about: 1) the culture (...) of organizations; 2) the organization of organizations; 3) the legal environment of organizations; 4) the role of professions in organizations; 5) the role of organizations in professions; or 6) the political environment of organizations. My conclusion is that, while all six are worthy subjects, there is neither much reason to believe that any of them are now absent from courses in engineering ethics nor an obvious way to decide whether they (individually or in combination) are (or are not) now being given their due. What we have here is a dispute about how much is enough. Such disputes are not to be settled without agreement concerning how we are to tell we have enough of this or that. Right now we seem to lack that agreement—and not to have much reason to expect it any time soon. (shrink)

One of the methods used at Penn State to teach engineering students about ethics is a one-credit First-Year Seminar entitled “How Good Engineers Solve Tough Problems.” Students meet in class once a week to understand ethical frameworks, develop ethical problem-solving skills, and to better understand the professional responsibilities of engineers. Emphasis is on the ubiquity of ethical problems in professional engineering. A learning objective is the development of moral imagination, similar to the development of technical imagination in (...) engineering design courses. Making sound arguments is also addressed in the process of reasoning through cases, and critiquing other’s arguments. Over the course of the semester, students solve five engineering ethics cases. Each week, a student team of four people is responsible for reading the assigned section of the text, developing a summary, and leading the class discussion. (shrink)

The use of role-playing (“active learning”) as a teaching tool has been reported in areas as diverse as social psychology, history and analytical chemistry. Its use as a tool in the teaching of engineering ethics and professionalism is also not new, but the approach develops new perspectives when used in a college class of exceptionally wide cultural diversity. York University is a large urban university (40,000 undergraduates) that draws its enrolment primarily from the Greater Toronto Area, arguably one (...) of the most culturally diverse cities in the world, embracing the largest percentage of Canada’s immigration. Among the area’s five million inhabitants, 50% identify themselves as a visible minority born outside Canada, while over 100 languages and dialects are spoken daily. Although students admitted from this international pool have usually been exposed to western attitudes during secondary education and are rapidly assimilated into Canadian culture, responses to specific ethical issues are strongly influenced by their prior culture. Two and three-part scripts for case studies based on NSF or original scenarios were written to illustrate issues such as gifts, attitudes towards women and ethnic minorities, conflict of interest, whistle-blowing, sexual harassment, individual rights, privacy, environment, intellectual property, and others. Following the presentation, the actors lead group discussion based on previously specified questions. Once the initial shyness and reluctance of some cultures has been overcome through the building of rapport, students have written original scripts based on hypothetical or prior personal situations. The method is now being adopted in a short course format to assist the professional integration of foreign trained engineers. (shrink)

Introduction to Engineering Ethics provides the background for discussion of the basic issues in engineering ethics. Emphasis is given to the moral problems engineers face in the corporate setting. It places those issues within a philosophical framework, and it seems to exhibit both their social importance and their intellectual challenge. The primary goal is to stimulate critical and responsible reflection on moral issues surrounding engineering practice and to provide the conceptual tools necessary for pursuing those (...) issues. As per new ABET 2000 guidelines, more and more introductory engineering courses cover engineering ethics as part of their instruction. Students preparing to function within the engineering profession need to be introduced to the basic issues in engineering ethics. This book places those issues within a wider philosophical framework than has been customary in the past and aims to stimulate critical and responsible reflection on the moral issues surrounding engineering practice and to provide the conceptual tools necessary for pursuing those issues. (shrink)

In 1998, a lead researcher at a Midwestern university submitted as his own a document that had 64 instances of strings of 10 or more words that were identical to a consultant’s masters thesis and replicated a data chart, all of whose 16 entries were identical to three and four significant figures. He was fired because his actions were wrong. Curiously, he was completely unable to see that his actions were wrong. This phenomenon is discussed in light of recent advances (...) in neuroscience and used to argue for a change in the standard way engineering ethics is taught. I argue that engineering ethics is better taught in the form of a design course in order to maximize “somatic” learning. (shrink)

A group of engineering students at the Technical University of Berlin, Germany, designed a course on engineering ethics. The core element of the developed Blue Engineering course are self-contained teaching-units, “building blocks”. These building blocks typically cover one complex topic and make use of various teaching methods using moderators who lead discussions, rather than experts who lecture. Consequently, the students themselves started to offer the credited course to their fellow students who take an active role in (...) further developing the course themselves. (shrink)

In order to fulfill ABET requirements, Northern Arizona University’s Civil and Environmental engineering programs incorporate professional ethics in several of its engineering courses. This paper discusses an ethics module in a 3rd year engineering design course that focuses on the design process and technical writing. Engineering students early in their student careers generally possess good black/white critical thinking skills on technical issues. Engineering design is the first time students are exposed to “grey” (...) or multiple possible solution technical problems. To identify and solve these problems, the engineering design process is used. Ethical problems are also “grey” problems and present similar challenges to students. Students need a practical tool for solving these ethical problems. The step-wise engineering design process was used as a model to demonstrate a similar process for ethical situations. The ethical decision making process of Martin and Schinzinger was adapted for parallelism to the design process and presented to students as a step-wise technique for identification of the pertinent ethical issues, relevant moral theories, possible outcomes and a final decision. Students had greatest difficulty identifying the broader, global issues presented in an ethical situation, but by the end of the module, were better able to not only identify the broader issues, but also to more comprehensively assess specific issues, generate solutions and a desired response to the issue. (shrink)

How can a course on engineering ethics affect an undergraduate student’s feelings of responsibility about moral problems? In this study, three groups of students were interviewed: six students who had completed a specific course on engineering ethics, six who had registered for the course but had not yet started it, and six who had not taken or registered for the course. Students were asked what they would do as the central character, an engineer, in each of (...) two short cases that posed moral problems. For each case, the role of the engineer was successively changed and the student was asked how each change altered his or her decisions about the case. Students who had completed the ethics course considered more options before making a decision, and they responded consistently despite changes in the cases. For both cases, even when they were not directly involved, they were more likely to feel responsible and take corrective action. Students who were less successful in the ethics course gave answers similar to students who had not taken the course. This latter group of students seemed to have weaker feelings of responsibility: they would say that a problem was “not my business.” It appears that instruction in ethics can increase awareness of responsibility, knowledge about how to handle a difficult situation, and confidence in taking action. (shrink)

Engineering is more cross-cultural and international than ever before, presenting challenges and opportunities in the way engineering ethics is conceived and delivered. To assist in providing more effective ethics education to increasingly diverse groups, this paper shares three related projects implemented at the University of Michigan-Shanghai Jiao Tong University Joint Institute (China). These projects are united in their attempts to address challenges arising from the increasingly global nature of engineering. The first is a course on (...) global engineering ethics, developed for and attended by engineering students from diverse backgrounds. The second is a website hosting contents on global engineering ethics education and conducting research related to cross-cultural moral psychology. The third explores methods of assessing engineering ethics and moral development, using paradigms of ethical decision-making. Although these projects were developed in a Chinese-US collaboration with university students, these contexts could facilitate the adoption of similar programs elsewhere, with practicing engineers. (shrink)

This paper discusses collaborative learning and its use in an elective course on ethics in engineering. Collaborative learning is a form of active learning in which students learn with and from one another in small groups. The benefits of collaborative learning include improved student performance and enthusiasm for learning, development of communication skills, and greater student appreciation of the importance of judgment and collaboration in solving real-world problems such as those encountered in engineering ethics. Collaborative learning (...) strategies employed in the course include informal small group discussions/problem solving, role-playing exercises, and cooperative student group projects, including peer grading. Student response to these techniques has been highly favorable. Realizing the benefits of collaborative learning is a challenge to both teachers, who must give up some control in the classroom, and students, who must be willing to take greater responsibility for their learning. (shrink)

A Publisher correction to this paper has been published: https://doi.org/10.1007/s40889-020-00118-8.

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)

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)

This article reports on the development and teaching of compulsory courses on ethics and engineering at Delft University of Technology (DUT). Attention is paid to the teaching goals, the educational setup and methods, the contents of the courses, involvement of staff from engineering schools, experiences to date, and challenges for the future. The choices made with respect to the development and teaching of the courses are placed within the European and Dutch context and are (...) compared and contrasted with the American situation and experiences. (shrink)

The literature on engineering ethics education highlights the diversity of goals and topics employed in its instruction. The contribution aims to examine the conceptualisation of engineering ethics education in terms of how it is defined and how its goals are articulated. The research is conducted in cooperation with the national accrediting body Engineers Ireland. It is based on interviews with instructors teaching courses self-identified by engineering programmes as having a strong ethical component and evaluators (...) serving on accreditation panels. The main findings confirm the existence of a varied and uneven understanding of engineering ethics education. The study encountered conflicting views and lack of clarity as to what falls under the scope of engineering ethics education, especially when considering the topics of sustainability and safety. In terms of goals, instructors emphasize fostering responsibility, enabling agency and developing broad and critical thinkers, while value sensitive design was found to have a lesser conceptual prominence. The study also found that engineering ethics is preponderantly defined through its connection to engineering practice, rather than in its theoretical dimension. The chapter is envisioned to contribute to debates tracing the conceptual domain of engineering ethics education, given that clarifying educational goals is an important prerequisite for employing and designing consistent instructional methods. (shrink)

This paper details a three-credit-hour undergraduate ethics course that was delivered using traditional, distance, and compressed formats. OLS 263: Ethical Decisions in Leadership is a 200-level course offered by the Department of Organizational Leadership and Supervision in the Purdue School of Engineering and Technology at Indiana University Purdue University Indianapolis (IUPUI). Students in engineering, technology, business, nursing, and other majors take the course. In an effort to determine student perceptions of course and instructor effectiveness, end-of-course student survey (...) data were compared using data from traditional, distance, and compressed sections of the course. In addition, learning outcomes from the final course project were evaluated using a standardized assessment rubric and scores on the course project. (shrink)

Cheating in the undergraduate classroom is not a new problem, and it is recognized as one that is endemic to the education system. This paper examines the highly normative behavior of using unauthorized assistance (e.g., a solutions manual or a friend) on an individual assignment within the context of an upper division undergraduate course in engineering mechanics. The findings indicate that there are varying levels of accepting responsibility among the students (from denial to tempered to full) and that acceptance (...) of responsibility can lead to identification of learning and necessary behavioral changes. The findings have implications for institutions and engineering faculty, in particular the need for consistent academic integrity education and the teaching of professional integrity and ethics. (shrink)

Societal pressures, accreditation organizations, and licensing agencies are emphasizing the importance of ethics in the engineering curriculum. Traditionally, this subject has been taught using dogma, heuristics, and case study approaches. Most recently a number of organizations have sought to increase the utility of these approaches by utilizing the Internet. Resources from these organizations include on-line courses and tests, videos, and DVDs. While these individual approaches provide a foundation on which to base engineering ethics, they may (...) be limited in developing a student’s ability to identify, analyze, and respond to engineering ethics situations outside of the classroom environment. More effective approaches utilize a combination of these types of approaches. This paper describes the design and development of an internet based interactive Simulator for Engineering Ethics Education. The simulator places students in first person perspective scenarios involving different types of ethical situations. Students must gather data, assess the situation, and make decisions. This requires students to develop their own ability to identify and respond to ethical engineering situations. A limited comparison between the internet based interactive simulator and conventional internet web based instruction indicates a statistically significant improvement of 32% in instructional effectiveness. The simulator is currently being used at the University of Houston to help fulfill ABET requirements. (shrink)

This paper outlines the development and implementation of a new course in Engineering Ethics at the University of Tennessee. This is a three-semester-hour course and is jointly taught by an engineering professor and a philosophy professor. While traditional pedagogical techniques such as case studies, position papers, and classroom discussions are used, additional activities such as developing a code of ethics and student-developed scenarios are employed to encourage critical thinking. Among the topics addressed in the course are (...) engineering as a profession and its role in society; ethical successes and failures; risk, safety, and the environment; professional responsibilities; credit and intellectual property; and international concerns. (shrink)

This paper articulates an Aristotelian theory of professional virtue and provides an application of that theory to the subject of engineering ethics. The leading idea is that Aristotle’s analysis of the definitive function of human beings, and of the virtues humans require to fulfill that function, can serve as a model for an analysis of the definitive function or social role of a profession and thus of the virtues professionals must exhibit to fulfill that role. Special attention is (...) given to a virtue of professional self-awareness, an analogue to Aristotle’s phronesis or practical wisdom. In the course of laying out my account I argue that the virtuous professional is the successful professional, just as the virtuous life is the happy life for Aristotle. I close by suggesting that a virtue ethics approach toward professional ethics can enrich the pedagogy of professional ethics courses and help foster a sense of pride and responsibility in young professionals. (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)

Ethics teaching in engineering can be problematic because of student perceptions of its subjective, ambiguous and philosophical content. The use of discipline-specific case studies has helped to address such perceptions, as has practical decision making and problem solving approaches based on some ethical frameworks. However, a need exists for a wider range of creative methods in ethics education to help complement the variety of activities and learning experiences within the engineering curriculum. In this work, a novel (...) approach is presented in which first-year undergraduate students are responsible for proposing ethics education activities of relevance to their peers and discipline area. The students are prepared for the task through a short introduction on engineering ethics, whereby generic frameworks for moral and professional conduct are discussed, and discipline and student-relevance contexts provided. The approach has been used in four departments of engineering at Imperial College London, and has led to the generation of many creative ideas for wider student engagement in ethics awareness, reflection and understanding. The paper presents information on the premise of the introductory sessions for supporting the design task, and an evaluation of the student experience of the course and task work. Examples of proposals are given to demonstrate the value of such an approach to teachers, and ultimately to the learning experiences of the students themselves. (shrink)

This paper considers an approach to teaching ethics in bioengineering based on the How People Learn (HPL) framework. Curricula based on this framework have been effective in mathematics and science instruction from the kindergarten to the college levels. This framework is well suited to teaching bioengineering ethics because it helps learners develop “adaptive expertise”. Adaptive expertise refers to the ability to use knowledge and experience in a domain to learn in unanticipated situations. It differs from routine expertise, which (...) requires using knowledge appropriately to solve routine problems. Adaptive expertise is an important educational objective for bioengineers because the regulations and knowledge base in the discipline are likely to change significantly over the course of their careers. This study compares the performance of undergraduate bioengineering students who learned about ethics for stem cell research using the HPL method of instruction to the performance of students who learned following a standard lecture sequence. Both groups learned the factual material equally well, but the HPL group was more prepared to act adaptively when presented with a novel situation. (shrink)

A course in professional ethics for civil engineers was taught for the first time in Spain during the academic year 2007/08. In this paper a survey on the satisfaction and expectation of the course is presented. Surprisingly the students sought moral and ethical principles for their own ordinary lives as well as for their profession. Students were concerned about the law, but in their actions they were more concerned with their conscience, aware that it can be separate from the (...) law. (shrink)

The graduate course in research ethics in the Graduate School for Integrative Sciences and Engineering at the National University of Singapore consists of a semester long mandatory course titled: “Research Ethics and Scientific Integrity.” The course provides students with guiding principles for appropriate conduct in the professional and social settings of scientific research and in making morally weighted and ethically sound decisions when confronted with moral dilemmas. It seeks to enhance understanding and appreciation of the moral reasoning (...) underpinning various rules and legislative constraints associated with research subjects and procedures. Further, students are trained to critically analyse cases and issues associated with scientific misconduct preparing them to act in a responsible and effective manner should they encounter such cases. The diverse background and training of the cohort also provide a unique setting and opportunity for student-initiated collaborative interdisciplinary learning. This article offers a reflective account of the course and some preliminary insights into learning outcomes. (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)

Cultivating an understanding of ethical responsibilities and the societal impacts of technology is increasingly recognized as an important component in undergraduate engineering curricula. There is growing research on how ethics-related topics are taught and outcomes are attained, especially in the context of accreditation criteria. However, there is a lack of theoretical and empirical understanding of the role that educators play in ethics and societal impacts instruction and the factors that motivate and shape their inclusion of this subject (...) in the courses they teach and co-curricular activities they mentor. The goal of this research was to explore the role of faculty’s personal influences on their inclusion of ESI instruction in these settings. Personal influences are distinguished from external or environmental drivers such as teaching assignments, university policies, and department curriculum decisions. This research employed a grounded theory methodology and extracted data from interviews with 19 educators who teach ESI to engineering students to develop an emergent conceptualization of personal influences. Four categorie were identified: intrapersonal, interpersonal, academic, and professional. The findings suggested a wide range of entry points into ESI instruction for faculty members who do not currently teach ESI and for those looking to expand the inclusion of ESI in their courses. Based on these findings, departments and administrators are encouraged to foster educators’ agency, support access to professional development and engagement, facilitate interdisciplinary collaboration, and broaden hiring decisions to account for the impact of educators’ holistic identity on their instruction. (shrink)

It is widely accepted that translational research practitioners need to acquire special skills and knowledge that will enable them to anticipate, analyze, and manage a range of ethical issues. While there is a small but growing literature that addresses the ethics of translational research, there is a dearth of scholarship regarding how this might apply to engineers. In this paper we examine engineers as key translators and argue that they are well positioned to ask transformative ethical questions. Asking engineers (...) to both broaden and deepen their consideration of ethics in their work, however, requires a shift in the way ethics is often portrayed and perceived in science and engineering communities. Rather than interpreting ethics as a roadblock to the success of translational research, we suggest that engineers should be encouraged to ask questions about the socio-ethical dimensions of their work. This requires expanding the conceptual framework of engineering beyond its traditional focus on “how” and “what” questions to also include “why” and “who” questions to facilitate the gathering of normative, socially-situated information. Empowering engineers to ask “why” and “who” questions should spur the development of technologies and practices that contribute to improving health outcomes. (shrink)

We present a graduate science ethics course that connects cases from the historical record to present realities and practices in the areas of social responsibility, authorship, and human/animal experimentation. This content is delivered with mixed methods, including films, debates, blogging, and practicum; even the instructional team is mixed, including a historian of science and a research scientist. What really unites all of the course’s components is the experiential aspect: from acting in historical debates to participating in the current scientific (...) enterprise. The course aims to change the students’ culture into one deeply devoted to the science ethics cause. To measure the sought after cultural change, we developed and validated a relevant questionnaire. Results of this questionnaire from students who took the course, demonstrate that the course had the intended effect on them. Furthermore, results of this questionnaire from controls indicate the need for cultural change in that cohort. All these quantitative results are reinforced by qualitative outcomes. (shrink)

Engineering, as a profession and business, is at the sharp end of the ethical practice. Far from being a bolt on extra to the ‘real work’ of the engineer it is at the heart of how he or she relates to the many different stakeholders in the engineering project. Engineering, Business and Professional Ethics highlights the ethical dimension of engineering and shows how values and responsibility relate to everyday practice. Looking at the underlying value systems (...) that inform practical thinking the book offers a framework for ethical decision-making. Covering global corporate responsibility to the increasing concern for the environment within the engineering business, the book offers ways in which value conflict can be handled. Integrating practice, value and diversity the book helps to prepare the engineer for the ethical challenges of the 21st century. This book is essential reading for all students on courses accredited by the Engineering Council e.g. Civil, Chemical, Mechanical and Environmental Engineering who need to be aware of ethics. Also of interest to practicing engineers and professionals such as Sustainability Managers and Community Workers involved in engineering projects. The authors have worked together in the area of engineering, professional and business ethics for many years and are all members of the National Centre for Applied Ethics at the University of Leeds. •Integrates ethical considerations into everyday decision-making •Shows how to review and overcome professional ethical problems •Practical case studies and examples throughout. (shrink)

Online information intermediaries such as Facebook and Google are slowly replacing traditional media channels thereby partly becoming the gatekeepers of our society. To deal with the growing amount of information on the social web and the burden it brings on the average user, these gatekeepers recently started to introduce personalization features, algorithms that filter information per individual. In this paper we show that these online services that filter information are not merely algorithms. Humans not only affect the design of the (...) algorithms, but they also can manually influence the filtering process even when the algorithm is operational. We further analyze filtering processes in detail, show how personalization connects to other filtering techniques, and show that both human and technical biases are present in today’s emergent gatekeepers. We use the existing literature on gatekeeping and search engine bias and provide a model of algorithmic gatekeeping. (shrink)

It has been argued that the Internet and social media increase the number of available viewpoints, perspectives, ideas and opinions available, leading to a very diverse pool of information. However, critics have argued that algorithms used by search engines, social networking platforms and other large online intermediaries actually decrease information diversity by forming so-called “filter bubbles”. This may form a serious threat to our democracies. In response to this threat others have developed algorithms and digital tools to combat filter bubbles. (...) This paper first provides examples of different software designs that try to break filter bubbles. Secondly, we show how norms required by two democracy models dominate the tools that are developed to fight the filter bubbles, while norms of other models are completely missing in the tools. The paper in conclusion argues that democracy itself is a contested concept and points to a variety of norms. Designers of diversity enhancing tools must thus be exposed to diverse conceptions of democracy. (shrink)

How do engineering educators adequately and richly introduce to young engineers the perplexing ethical issues associated with the development of new technologies? Robotics, nanotechnology, cloning, cyberintelligence, and genetic engineering, for example, each hold the potential to radically alter the fundamental nature of human life. Senior citizens in our society have a lifetime of experience adopting new technologies into their lives. Through an intergenerational dialogue, undergraduate engineers can come to appreciate and understand what technological change can really mean, both (...) in practical and ethical terms. This article explores the use of intergenerational dialogue as a learning tool, with a focus on the experience of students enrolled in a required engineering ethics course. Reactions and thoughts recounted in this article from both undergraduate engineers and senior citizens signify the immeasurable educational value of intergenerational exploration and its effectiveness in examining the ethical questions connected to the development of new technologies. (shrink)

In this paper we present the authors’ experience of teaching a course in Ethics for Engineers, which has been delivered four times in three different universities in Spain and Chile. We begin by presenting the material context of the course, and especially the intellectual background of the participating students, in terms of their previous understanding of philosophy in general, and of ethics in particular. Next we set out the objectives of the course and the main topics addressed, as (...) well as the methodology and teaching resources employed to have students achieve a genuine philosophical reflection on the ethical aspects of the profession, starting from their own mindset as engineers. Finally we offer some results based on opinion surveys of the students, as well as a more personal assessment by the authors, recapitulating the most significant achievements of the course and indicating its underlying Socratic structure. (shrink)

Societal and ethical implications of nanotechnology have become a hot topic of public debates in many countries because both revolutionary changes and strong public concerns are expected from its development. Because nanotechnology is, at this point, mostly articulated in visionary and futuristic terms, it is difficult to apply standard methods of technology assessment and even more difficult to consider it in engineering ethics courses. In this article, the authors suggest using selected science fiction stories in the (...) class='Hi'>engineering ethics classroom to provide students with ethical skills and cultural knowledge required for engaging in public debates and for responsible decision making. Against the background of general debates on teaching engineering ethics, they do so by discussing the advantages and possible drawbacks of this approach and by presenting two examples of nano-science fiction classics. (shrink)

In this paper I outline an “agent-centered” approach to learning ethics. The approach is “agent-centered” in that its central aim is to prepare students toact wisely and responsibly when faced with moral problems. The methods characteristic of this approach are suitable for integrating material on professional and research ethics into technical courses, as well as for free-standing ethics courses. The analogy I draw between ethical problems and design problems clarifies the character of ethical problems as (...) they are experienced by those who must respond to them. It exposes the mistake, common in ethics teaching, of misrepresenting moral problems as multiple-choice problems, especially in the form of ‘dilemmas’, that is, a forced choice between two unacceptable alternatives. Furthermore, I clarify the importance for responsible practice of recognizing any ambiguity in the problem situation. (shrink)

Increasingly complex working environments of school principals inevitably led them to face moral dilemmas in daily life. The aim of this research is to reveal which kinds of moral dilemmas principals fall into mostly, how principals follow the road to making decisions in the moral dilemmas, and if the nature of management affects the decision-making process of their moral dilemmas or not. For data collection process snowball sampling was used. Semi-structured interviews and vignettes which were designed by researchers were used (...) for data collection. According to results, principals in Turkey have experienced moral dilemmas based on self-interests instead of ethic of critique which is experienced by Canadian principals. Moreover, taking into consideration the decision-making process, although principals in Canada follow the same procedure as the Turkish principals, they have two extra steps: “considering the students’ benefit” and “considering teachers’ and parents’ needs.” Lastly, it is seen that the Turkish and Canadian principals’ natures which affect the moral dilemma decision-making process are totally different. The possible reasons for these differences and suggestions were discussed within this context. (shrink)

Ethical questions posed by emerging technologies call for greater understanding of their societal, economic, and environmental aspects by policymakers, citizens, and the engineers and applied scientists at the heart of their development and application. This article reports on the efforts of one research project that assessed the growth of critical thinking and awareness of these multiple aspects in undergraduate engineering and applied science students, with specific regard to nanotechnology. Students in two required courses, a first-year writing and (...) class='Hi'>engineering ethics course and a second-year social science course, went through nanotechnology modules as a part of their regular coursework. In the first-year humanities course, we observed self-reported increases in risk awareness, significant educational impact of the module, and a greater awareness of nanotechnology’s applications and social context. In the second-year social science course, we noted changes in risk/benefit analysis as well as in the character and depth of students’ historical analysis, but no change in comparative awareness of other topics, including labor issues and corporate motivations. (shrink)

At a conference, two engineering professors and a philosophy professor discussed the teaching of ethics in engineering and computer science. The panelists considered the integration of material on ethics into technical courses, the role of ethical theory in teaching applied ethics, the relationship between cases and codes of ethics, the enlisting of support of engineering faculty, the background needed to teach ethics, and the assessment of student outcomes. Several audience members contributed (...) comments, particularly on teaching ethical theory and on student assessment. (shrink)

Ethical questions posed by emerging technologies call for greater understanding of their societal, economic, and environmental aspects by policymakers, citizens, and the engineers and applied scientists at the heart of their development and application. This article reports on the efforts of one research project that assessed the growth of critical thinking and awareness of these multiple aspects in undergraduate engineering and applied science students, with specific regard to nanotechnology. Students in two required courses, a first-year writing and (...) class='Hi'>engineering ethics course and a second-year social science course, went through nanotechnology modules as a part of their regular coursework. In the first-year humanities course, we observed self-reported increases in risk awareness, significant educational impact of the module, and a greater awareness of nanotechnology’s applications and social context. In the second-year social science course, we noted changes in risk/benefit analysis as well as in the character and depth of students’ historical analysis, but no change in comparative awareness of other topics, including labor issues and corporate motivations. (shrink)

There is growing need for hybrid curricula that integrate constructivist methods from Science and Technology Studies (STS) into both engineering and policy courses at the undergraduate and graduate levels. However, institutional and disciplinary barriers have made implementing such curricula difficult at many institutions. While several programs have recently been launched that mix technical training with consideration of “societal” or “ethical issues,” these programs often lack a constructivist element, leaving newly-minted practitioners entering practical fields ill-equipped to unpack the politics (...) of knowledge and technology or engage with skeptical publics. This paper presents a novel format for designing interdisciplinary coursework that combines conceptual content from STS with training in engineering and policy. Courses following this format would ideally be team taught by instructors with advanced training in diverse fields, and hence co-learning between instructors and disciplines is a key element of the format. Several instruments for facilitating both student and instructor collaborative learning are introduced. The format is also designed for versatility: in addition to being adaptable to both technical and policy training environments, topics are modularized around a conceptual core so that issues ranging from biotech to nuclear security can be incorporated to fit programmatic needs and resources. (shrink)