In France, some institutions seem to call for the engineer’s sense of social responsibility. However, this call is scarcely heard. Still, engineering students have been given the opportunity to gain a general education through courses in literature, law, economics, since the nineteenth century. But, such courses have long been offered only in the top ranked engineering schools. In this paper, we intend to show that the wish to increase engineering students’ social responsibility is an old concern. We also aim at (...) highlighting some macro social factors which shaped the answer to the call for social responsibility in the French engineering “Grandes Ecoles”. In the first part, we provide an overview of the scarce attention given to the engineering curriculum in the scholarly literature in France. In the second part, we analyse one century of discourses about the definition of the “complete engineer” and the consequent role of non technical education. In the third part, we focus on the characteristics of the corpus which has been institutionalized. Our main finding is that despite the many changes which occurred in engineering education during one century, the “other formation” remains grounded on a non academic “way of knowing”, and aims at increasing the reputation of the schools, more than enhancing engineering students’ social awareness. (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 ethics entails three frames of reference: individual, professional, and social. “Microethics” considers individuals and internal relations of the engineering profession; “macroethics” applies to the collective social responsibility of the profession and to societal decisions about technology. Most research and teaching in engineering ethics, including online resources, has had a “micro” focus. Mechanisms for incorporating macroethical perspectives include: integrating engineering ethics and science, technology and society (STS); closer integration of engineering ethics and computer ethics; and consideration of the influence of (...) professional engineering societies and corporate social responsiblity programs on ethical engineering practice. Integrating macroethical issues and concerns in engineering ethics involves broadening the context of ethical problem solving. This in turn implies: developing courses emphasizing both micro and macro perspectives, providing faculty development that includes training in both STS and practical ethics; and revision of curriculum materials, including online resources. Multidisciplinary collaboration is recommended 1) to create online case studies emphasizing ethical decision making in individual, professional, and societal contexts; 2) to leverage existing online computer ethics resources with relevance to engineering education and practice; and 3) to create transparent linkages between public policy positions advocated by professional societies and codes of ethics. (shrink)

The need to make young scientists aware of their social responsibilities is widely acknowledged, although the question of how to actually do it has so far gained limited attention. A 2-day workshop entitled “Prepared for social responsibility?” attended by doctoral students from multiple disciplines in climate science, was targeted at the perceived needs of the participants and employed a format that took them through three stages of ethics education: sensitization, information and empowerment. The workshop aimed at preparing doctoral students to (...) manage ethical dilemmas that emerge when climate science meets the public sphere (e.g., to identify and balance legitimate perspectives on particular types of geo-engineering), and is an example of how to include social responsibility in doctoral education. The paper describes the workshop from the three different perspectives of the authors: the course teacher, the head of the graduate school, and a graduate student. The elements that contributed to the success of the workshop, and thus make it an example to follow, are (1) the involvement of participating students, (2) the introduction of external expertise and role models in climate science, and (3) a workshop design that focused on ethical analyses of examples from the climate sciences. (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)

Projects importing technology to lesser developed nations may raise five important concerns: famine resulting from substitution of cash crops for subsistence crops, the use of products banned in the United States but permitted overseas, the use of products safe in the U.S. but unsafe under local conditions, ecological consequences of technological change, and cultural disruption caused by displacing traditional ways of life. Are engineers responsible for the foreseeable hunger, environmental degradation, cultural disruption, and illness that results from the project? Are (...) engineers guilty of paternalism if they refuse to accept the project for that reason? Criteria are given to help engineers assess the extent of their responsibility when working in lesser developed nations. (shrink)

In order to raise awareness of the ambiguous nature of scientific-technological progress, and of the challenging problems it raises, problems which are not easily addressed by courses in a single discipline and cannot be projected onto disciplinary curricula, Technical University of Darmstadt has established three interdisciplinary study concentrations: “Technology and International Development”, “Environmental Sciences”, and “Sustainable Shaping of Technology and Science”. These three programmes seek to overcome the limitations of strictly disciplinary research and teaching by developing an integrated, problem-oriented approach. (...) For example, one course considers fundamental nuclear dilemmas and uses role-playing techniques to address a controversy in the area of nuclear security. At the same time, incorporating interdisciplinary teaching into a university that is organized around mono- or multi-disciplinary faculties also poses a number of challenges. Recognition in disciplinary curricula, and appropriate organizational support and funding are examples of those challenges. It is expected that science and engineering students, empowered by such interdisciplinary study programmes, will be better prepared to act responsibly with regard to scientific and technological challenges. (shrink)

Stimulated by Kenneth Pimple’s “Six Domains of Research Ethic”, this paper examines four aspects of the responsible conduct of research and scientists’ social responsibilities. I argue that scholars and decision-makers concerned with the responsible conduct of research should take notice of the rapidly growing body of scholarship on the social organization of science and the behavior of scientists, integrating that work with ethical principles. Of particular concern are the increasing heterogeneity and interdisciplinary of research, the ambivalences in the practice of (...) peer review, the social tensions of research life, and the heightened concern for social and economic returns from federal research investments. In all, the paper echoes and develops Pimple’s call for integrative thinking about the responsible conduct of research. (shrink)

Ethical conduct is the hallmark of excellence in engineering and scientific research, design, and practice. While undergraduate and graduate programs in these areas routinely emphasize ethical conduct, few receive formal ethics training as part of their curricula. The first purpose of this research study was to assess the relative effectiveness of ethics education in enhancing individuals’ general knowledge of the responsible conduct of research practices and their level of moral reasoning. Secondly, we examined the effects of ethics education on the (...) positive psychological outcomes of perspective-taking, moral efficacy, moral courage, and moral meaningfulness. To examine our research hypotheses, we utilized a pretest–posttest quasi-experimental design consisting of three ethics education groups (control, embedded modules, and stand-alone courses). Findings revealed that both embedded and stand alone courses were effective in enhancing participants’ perspective-taking, moral efficacy, and moral courage. Moral meaningfulness was marginally enhanced for the embedded module condition. Moral judgment and knowledge of responsible conduct of research practices were not influenced by either ethics education condition. Contrary to expectations, stand alone courses were not superior to embedded modules in influencing the positive psychological outcomes investigated. Implications of these findings for future research and practice are discussed. (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)

Die Theorie der Gerechtigkeit gehört zu den am intensivsten bestellten Feldern der zeitgenössischen Philosophie. Allerdings haben die meisten Gerechtigkeitstheorien ihr hohes Begründungsniveau nur um den Preis eines schweren Defizits erreicht, denn mit ihrer Fixierung auf rein normative, abstrakte Prinzipien geraten sie in beträchtliche Distanz zu jener Sphäre, die ihr”Anwendungsbereich“ist: der gesellschaftlichen Wirklichkeit. Zur Begründung dieses weitreichenden Unterfangens weist Honneth zunächst nach, daß alle wesentlichen Handlungssphären westlicher Gesellschaften ein Merkmal teilen: Sie haben den Anspruch, einen jeweils besonderen Aspekt von individueller Freiheit (...) zu verwirklichen. Im Geiste von Hegels Rechtsphilosophie und unter anerkennungstheoretischen Vorzeichen zeigt das zentrale Kapitel, wie in konkreten gesellschaftlichen Bereichen - in persönlichen Beziehungen, im marktvermittelten Wirtschaftshandeln und in der politischen Öffentlichkeit - die Prinzipien individueller Freiheit generiert werden, die die Richtschnur für Gerechtigkeit bilden. Das Ziel des Buches ist ein höchst anspruchsvolles: die Gerechtigkeitstheorie als Gesellschaftsanalyse neu zu begründen. (shrink)

The purpose of this paper is to provide a simple yet comprehensive organizing scheme for the responsible conduct of research (RCR). The heuristic offered here should prove helpful in research ethics education, where the many and heterogeneous elements of RCR can be bewildering, as well as research into research integrity and efforts to form RCR policy and regulations. The six domains are scientific integrity, collegiality, protection of human subjects, animal welfare, institutional integrity, and social responsibility.

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)

The Leuphana Semester at Leuphana University Lüneburg, together with the module “Science bears responsibility” demonstrate how innovative methods of teaching and learning can be combined with the topic of sustainable development and how new forms of university teaching can be introduced. With regard to module content, it has become apparent that, due to the complexity of the field of sustainability, a single discipline alone is unable to provide analyses and solutions. If teaching in higher education is to adequately deal with (...) this complexity, then it is necessary to develop inter- and transdisciplinary approaches that go beyond a purely specialist orientation. (shrink)

UNESCO is an intergovernmental organization with 193 Member States. It is concerned with a broad range of issues regarding education, science and culture. It is the only UN organisation with a mandate in science. Since 1993 it is addressing ethics of science and technology, with special emphasis on bioethics. One major objective of the ethics programme is the development of international normative standards. This is particularly important since many Member States only have a limited infrastructure in bioethics, lacking expertise, educational (...) programs, bioethics committees and legal frameworks. UNESCO has recently adopted the Universal Declaration on Bioethics and Human Rights. The focus of current activities is now on implementation of this Declaration. Three activities are discussed that aim at improving and reinforcing the ethics infrastructure in relation to science and technology: the Global Ethics Observatory, the Ethics Education Programme and the Assisting Bioethics Committees project. (shrink)

This paper aims at contributing to a research agenda in engineering ethics by exploring the ethical aspects of engineering design processes. A number of ethically relevant topics with respect to design processes are identified. These topics could be a subject for further research in the field of engineering ethics. In addition, it is argued that the way design processes are now organised and should be organised from a normative point of view is an important topic for research.

In Spain before the 1990s there was no clear and explicit comprehensive training for future engineers with regard to social responsibility and social commitment. Following the Spanish university curricular reform, which began in the early 1990s, a number of optional subjects became available to students, concerning science, technology and society (STS), international cooperation, the environment and sustainability. The latest redefinition of the Spanish curriculum in line with the Bologna agreements has reduced the number of non-obligatory subjects, but could lead to (...) improving preparation for social responsibility due to the requirement that the design of curricula and the assessment of students should be based on competencies, some of which include human values and attitudes. (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)

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)

Two issues of particular interest in the Irish context are (1) the motivation for broadening engineering education to include the humanities, and an emphasis on social responsibility and (2) the process by which broadening can take place. Greater community engagement, arising from a socially-driven model of engineering education, is necessary if engineering practice is to move beyond its present captivity by corporate interests.

Extended Report from Working Group 5: Social Responsibility of Scientists at the 59th Pugwash Conference on Science and World Affairs in Berlin, 1–4 July 2011 Content Type Journal Article Pages 1-10 DOI 10.1007/s11948-011-9324-9 Authors Tom Børsen, Department of Learning and Philosophy, Aalborg University, Copenhagen, Lautrupvang 2, DK-2750 Ballerup, Denmark Journal Science and Engineering Ethics Online ISSN 1471-5546 Print ISSN 1353-3452.

As Kenneth Pimple points out, scientists’ responsibilities to the larger society have received less attention than ethical issues internal to the practice of science. Yet scientists and specialists who study science have begun to provide analyses of the foundations and scope of scientsts’ responsibilities to society. An account of contributions from Kristen Shrader-Frechette, Melanie Leitner, Ullica Segerstråle, John Ahearne, Helen Longino, and Carl Cranor offers work on scientists’ social responsibilities upon which to build.

Role plays are extremely valuable tools to address different aspects of teaching social responsibility, because they allow students to “live through” complex ethical decision making dilemmas. While role plays are getting high marks from students because their entertainment value is high, their educational value depends on their closeness to students’ work experience and the skills of the teacher in helping students comprehend the lessons they are meant to convey.

Interdisciplinary courses on science, engineering and society have been successfully established in two cases, at Bilkent University, Ankara, Turkey, and at the University of Hamburg, Germany. In both cases there were institutional and perceptual barriers that had to be overcome in the primarily disciplinary departments. The ingredients of success included a clear vision of interdisciplinary themes and didactics, and the exploitation of institutional opportunities. Haldun M. Ozaktas in Ankara used the dynamics of an accreditation process to establish courses on engineering (...) and society. At the University of Hamburg the introduction of optional courses into all curricula allowed for the establishment of a seminar series on physics and society, as well as on peace education and peace building. Both of these approaches have a weakness in common: the courses can disappear once their initiators have left, unless the interdisciplinary themes are integrated into compulsory core curricula. (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)

The key stakeholders of the Finnish engineering education collaborated during 2006–09 to reform the system of education, to face the challenges of the changing business environment and to create a national strategy for the Finnish engineering education. The work process was carried out using participatory work methods. Impacts of sustainable development (SD) on engineering education were analysed in one of the subprojects. In addition to participatory workshops, the core part of the work on SD consisted of a research with more (...) than 60 interviews and an extensive literature survey. This paper discusses the results of the research and the work process of the Collaboration Group in the subproject of SD. It is suggested that enhancing systematic dialogue among key stakeholders using participatory work methods is crucial in increasing motivation and commitment in incorporating SD in engineering education. Development of the context of learning is essential for improving skills of engineering graduates in some of the key abilities related to SD: systemic- and life-cycle thinking, ethical understanding, collaborative learning and critical reflection skills. This requires changing of the educational paradigm from teacher-centred to learner-centred applying problem- and project-oriented active learning methods. (shrink)

This commentary on K.D. Pimple’s “Six Domains of Research Ethics”, focuses on the area of institutional integrity and looks at “relationships between researchers, their sponsoring institutions, funding agencies, and the government,” considering the implications of institutional demands and support for research, and, in turn, demands and support on research priorities and public education.

This article focuses mainly on (1) the policy of Delft University of Technology since 1992 as regards the university-wide introduction of a compulsory course on ethics and engineering, and (2) the ideal structure of such a course, including the educational goals of the course.

This article focuses mainly on (1) the policy of Delft University of Technology since 1992 as regards the university-wide introduction of a compulsory course on ethics and engineering, and (2) the ideal structure of such a course, including the educational goals of the course.

Advances in the life sciences are occurring with extreme rapidity and accumulating a great deal of knowledge about life’s vital processes. While this knowledge is essential for fighting disease in a more effective way, it can also be misused either intentionally or inadvertently to develop novel and more effective biological weapons. For nearly a decade civil-academic society as well as States Parties to the Biological and Toxin Weapons Convention have recognised the importance of dual-use biosecurity education for life scientists as (...) a means to foster a culture of responsibility and prevent the potential misuse of advances in the life sciences for non-peaceful purposes. Nevertheless, the implementation of dual-use biosecurity education for life scientists has made little progress in institutions of higher learning. Professional societies and academic organizations have worked from the bottom-up in developing online dual-use biosecurity education modules that can be used for instruction. However, top-down help is needed from goverments if further progress is to be made in implementing biosecurity education for life scientists. (shrink)

This paper aims to present possible approaches, resources and programmes to introduce the topic of biosecurity to life scientists and engineers at the higher education level. Firstly, we summarise key findings from a number of international surveys on biosecurity education that have been carried out in the United States, Europe, Israel and the Asia–Pacific region. Secondly, we describe the development of our openly-accessible education resource, illustrating the scope and content of these materials. Thirdly, we report on actual cases of biosecurity (...) education that have been implemented. These include achievements in and lessons derived from the implementation of biosecurity education at the National Defense Medical College in Japan. These experiences are followed by presentation of the expert-level “Train-the-Trainer” programmes subsequently launched by the University of Bradford in the United Kingdom. These examples will help readers to understand how educators can enhance their own understanding about biosecurity issues and how they can then disseminate their knowledge through development of their own customised, relevantly-targeted and stage-tailored education programmes within their own life science communities. By providing these examples, we argue that education for life scientists, policy-makers and other stakeholders about social responsibility on dual-use issues is easily achievable and need not be expensive, time-consuming or over-burdening. We suggest that recurring classes or courses be held at appropriate times during educational programmes to accommodate the developing expertise and advancing learning stages of students. (shrink)

Increasing numbers of engineers from developed countries are employed during some part of their careers in lesser-developed nations (LDN’s), or they may design products for use in LDN’s. Yet determining the implications of professional engineering codes for engineers’ conduct in such settings can be difficult. Conditions are often substantially different from those in developed countries, where the codes were formulated. In this paper I explore the implications of what I call the “welfare requirement” in engineering codes for professional engineering conduct (...) in LDN’s. (shrink)

Society invests in the education of engineers because it is expected that the works of engineers will bring good results for society. Because the work of engineers is not value free or neutral, it is important that engineers are educated in the important principles of the social sciences and humanities. This education is essential for the awareness and understanding of what is good for society. Therefore the concept of sustainable development should be part of an education in engineering but only (...) when the social sciences are also a part of it. (shrink)