Nanotechnology, the emerging capability of human beings to observe and organize matter at the atomic level, has captured the attention of the federal government, science and engineering communities, and the general public. Some proponents are referring to nanotechnology as “the next technological revolution”. Applications projected for this new evolution in technology span a broad range from the design and fabrication of new membranes, to improved fuel cells, to sophisticated medical prosthesis techniques, to tiny intelligent machines whose impact on humankind is (...) unknowable. As with the appropriation of technological innovation generally, nanotechnology is likely to eventually bring dramatic and unpredictable new capabilities to human material existence, along with resulting ethical challenges and social changes to be reconciled. But as of yet, aside from a few simple new consumer goods, such as paint, rackets and fabric coatings, nanotechnology is undeveloped. Its social and ethical dimensions are not apparent. Even still, given the stated goals of the various nanotechnology initiatives to rearrange matter with increasing atomic precision, the impact of nanotechnology on human life and society is likely be profound. It is very difficult, however, to make accurate predictions about the future impact of nanotechnology development on humanity. At this time, the most important role for ethics analysis is to contribute to a humanitarian, conscientious approach to its development. This paper suggests that such an approach requires that attention be given to the roles of imagination, meaning-making, metaphor, myth and belief. (shrink)

At present there is an enormous discrepancy between our nanotechnological capabilities (particularly our nanobiotechnologies), our social wisdom, and consensus on how to apply them. To date, cost considerations have greatly constrained our application of nanotechnologies. However, novel advances in microsystem platform technologies are about to greatly diminish that economic constraint while developing new industries. Properly used in a solid legal and ethical framework, within an educated population, these advances will vastly enrich our quality of life without being intrusive. Improperly used, (...) these technologies could lead to a modern-day Luddism, social turmoil, or possibly even to emulating those societies described in the darkest of novels. These technologies must be developed in tandem with the social and legal frameworks needed to ensure that they improve both individuals and our society. To ensure that this occurs, we need to have the ethical, legal, scientific, and engineering experts working together and with the public. (shrink)

AbeBooks.com: The Technological Society.

Research scientists are trained to produce specialised bricks of knowledge, but not to look at the whole building. Increasing public concern about the social role of science is forcing science students to think about what they are actually learning to do. What sort of knowledge will they be producing, and how will it be used? Science education now requires serious consideration of these philosophical and ethical questions. But the many different forms of knowledge produced by modern science cannot be covered (...) by any single philosophical principle. Sociology and cognitive psychology are also needed to understand what the sciences have in common and the significance of what they generate. Again, traditional modes of ethical analysis cannot deal adequately with the values, norms and interests activated by present-day technoscience without reference to its sociological, political and economic dimensions. (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)

Rapid advances in nanoscience and nanotechnology are profoundly influencing the ways in which we conceptualize the world of the future, and human ability to manipulate matter at the atomic and molecular levels offers previously unimagined possibilities for scientific discovery and technological applications. The convergence of nanotechnology with biotechnology, information technology, cognitive science, and engineering may hold promise for the improvement of human performance at a number of levels. Based on a National Science Foundation-funded Research Experiences for Undergraduates Program in nanoscience (...) and nanotechnology at the University of Central Florida (summer 2002), a variety of social and ethical issues associated with these advances is discussed. Implications for the future of science-technology-society studies and K-16 science education also are presented. (shrink)

This paper briefly summarizes current thinking in engineering ethics education, argues that much of that ethical instruction runs the risk of being only superficially effective, and explores some of the underlying systemic barriers within academia that contribute to this result. This is not to criticize or discourage efforts to improve ethics instruction. Rather it is to point to some more fundamental problems that still must be addressed in order to realize the full potential of enhanced ethics instruction. Issues discussed will (...) include: intellectual engagement versus emotional engagement; the gravitational pull of curricular structures; the nature of engineering faculty; and the “engineer-ization” of ethics. (shrink)

This paper briefly summarizes current thinking in engineering ethics education, argues that much of that ethical instruction runs the risk of being only superficially effective, and explores some of the underlying systemic barriers within academia that contribute to this result. This is not to criticize or discourage efforts to improve ethics instruction. Rather it is to point to some more fundamental problems that still must be addressed in order to realize the full potential of enhanced ethics instruction. Issues discussed will (...) include: intellectual engagement versus emotional engagement; the gravitational pull of curricular structures; the nature of engineering faculty; and the “engineer-ization” of ethics. (shrink)

Sociologists of science and others have long been interested in how advances in science come about, and their potential social and economic impacts. Developments in nanoscience and nanotechnology will provide social scientists with a unique opportunity to explore how scientific activities form de novo. Additionally, scientists will have the opportunity to examine the factors that drive science and technology in certain directions by considering how different models of innovation may explain how the topography of the knowledge-based economy is being shaped (...) by radically new approaches to science. (shrink)

Using Canada as a case study, this article argues that regulating biotechnology and nanotechnology is made unnecessarily complex and inherently unstable because of a failure to consult the public early and of-ten enough. Furthermore, it is argued that future regulators (and promoters) of nanotechnology may learn valuable lessons from the mistakes made in regulating biotechnology.

The study of engineering ethics tends to emphasize professional codes of ethics and, to lesser degrees, business ethics and technology studies. These are all important vantage points, but they neglect personal moral commitments, as well as personal aesthetic, religious, and other values that are not mandatory for all members of engineering. This paper illustrates how personal moral commitments motivate, guide, and give meaning to the work of engineers, contributing to both self-fulfillment and public goods. It also explores some general frameworks (...) for thinking about these commitments and calls for further exploration of them. (shrink)

This is an examination of three main strategies used by engineering educators to integrate ethics into the engineering curriculum. They are: (1) the standalone course, (2) the ethics imperative mandating ethics content for all engineering courses, and (3) outsourcing ethics instruction to an external expert. The expectations from each approach are discussed and their main limitations described. These limitations include the insular status of the stand-alone course, the diffuse and uneven integration with the ethics imperative, and the orphaned status of (...) ethics using the outside expert. A fourth option is proposed — a special modular option. This strategy avoids the limitations of earlier approaches and harmonizes well with curricular objectives and professional values. While some help is provided by a professional ethicist, the headliner for the series of seminars is a high-profile engineer who shares an ethics dilemma encountered in professional practice. Students discuss the case and propose solutions. (shrink)

Nanotechnology is science and engineering resulting from the manipulation of matter’s most basic building blocks: atoms and molecules. As such, nanotechnology promises unprecedented control over both the materials we use and the means of their production. Such control could revolutionize nearly every sector of our economy, including medicine, defense, and energy. Despite the relatively recent emergence of this field, it already enjoys generous federal funding and enthusiastic media coverage. The tenor of discourse on nanotechnology is changing, however, as the voices (...) of critics begin to sound about a host of concerns ranging from the societal impacts of improving human performance to the specter of environmental devastation and human disease. (shrink)

With the advent of the newest technologies, it is necessary for engineering to incorporate the integration of social responsibility and technical integrity. A possible approach to accomplishing this integration is by expanding the culture of the engineering profession so that it is more congruent with the complex nature of the technologies that are now being developed. Furthermore, in order to achieve this expansion, a shift in thinking is required from a linear or reductionist paradigm (atomistic, deterministic and dualistic) to a (...) nonlinear paradigm (holistic, chaotic and subjective). Three aspects of such a nonlinear paradigm (holism, transparency and responsiveness) enable an engineer to shift from “applying ethics” to “being ethical”. This culture change can be a basis for developing new curricula to satisfy the ABET-2000 requirements as well as for the practice of engineering in the 21st Century. (shrink)

Biotechnology and nanotechnology are both strategic technologies, and the former provides several lessons that could contribute to more successful embedding and integration processes for the latter. This article identifies some of the key questions emerging from the biotechnology experience and summarizes several lessons learned in the context of constructive technology assessment. This approach broadens the range of social considerations relevant to the sustainable development of nanotechnology and emphasizes the need for developing social tools for nanotechnology innovation while the technology is (...) in its early stages of design. (shrink)

The revolutionary Feynman vision of a powerful and general nanotechnology, based on nanomachines that build with atom-by-atom control, promises great opportunities and, if abused, great dangers. This vision made nanotechnology a buzzword and launched the global nanotechnology race. Along the way, however, the meaning of the word has shifted. A vastly broadened definition of nanotechnology (including any technology with nanoscale features) enabled specialists from diverse fields to infuse unrelated research with the Feynman mystique. The resulting nanoscaletechnology funding coalition has obscured (...) the Feynman vision by misunderstanding its basis, distrusting its promise, and fearing that public concern regarding its dangers might interfere with research funding. In response, leaders of a funding coalition have attempted to narrow nanotechnology to exclude one area of nanoscale technology—the Feynman vision itself. Their misdirected arguments against the Feynman vision have needlessly confused public discussion of the objectives and consequences of nanotechnology research. (shrink)

Modern technology is more than a neutral tool: it is the framework of our civilization and shapes our way of life. Social critics claim that we must choose between this way of life and human values. Critical Theory of Technology challenges that pessimistic cliche. This pathbreaking book argues that the roots of the degradation of labor, education, and the environment lie not in technology per se but in the cultural values embodied in its design. Rejecting such popular solutions as economic (...) simplicity or spiritual renewal, Feenberg presents a compelling argument for broader democratic participation in technological choices. This book will be of special interest to scholars and students of philosophy, sociology, contemporary Marxism, and Critical Theory. (shrink)

These are some of the central questions that Robert Proctor addresses in his study of the politics of modern science.

No one really knows where nanotechnology is leading, what its pursuit will mean, and how it may affect human and other forms of life. Nevertheless, its research and development are moving briskly into that unknown. It has been suggested that rapid movement towards 'who knows where' is endemic to all technological development; that its researchers pursue it for curiosity and enjoyment, without knowing the consequences, believing that their efforts will be beneficial. Further, that the enthusiasm for development comes with no (...) malicious intent but rather from simple ignorance. Contrary to that commonly held perception about the collective pursuit of technological development, there are individual research scientists and engineers who are quite willing to reflect on the meaning of their work in nanotechnology. Nanotalk is a book of conversations and explorations with thirty five such nano-research scientists and engineers who share their ideas, experiences, perceptions, and beliefs about their work, humanity, nature, change, and the future of the world with nanotechnology. Precisely because of the unknowable nature of nanotechnology research and development, conscientious foresight and ethical reflection are warranted every step of the way. Not only do nanotechnology research and development represent enormous financial commitments, but they also require a profound leap of faith regarding its possible outcomes. Using these conversations as the basis of reflection and deliberation, the author explores the possible significance of nanotechnology to humanity and how it might be pursued conscientiously and ethically. (shrink)

As 'social and ethical issues' becomes a recurring phrase in the community paying attention to nanotechnology research, a crucial question becomes: what counts as a social and ethical issue? A typical list includes privacy, environmental health and safety, media hype, and other apparently unrelated issues. This article surveys those issues and suggests that concerns about fundamental concepts of ethics, such as fairness, justice, equity, and especially power, unite the various issues identified as 'social and ethical issues' in nanotechnology.

'Research, teaching, and service' is growing to include business. With unbridled enthusiasm, academicians bring discoveries to market instead of having them sit fallow in the public domain. Dilemmas have emerged. Academic scientists underwrite their work with public funds and employ a utilitarian labor force, namely, students seeking an education. The benefits from a successful business are significantly higher than in academic ventures, so the temptation increases to abrogate professional responsibilities and loyalties in favor of personal gain. Safeguards are needed for (...) the institution and its students while simultaneously permitting the development of scientifically, socially, and economically important discoveries. (shrink)

In a recent debate, Eric Drexler and Richard Smalley have discussed the chemical and physical possibility of constructing molecular assemblers - devices that guide chemical reactions by placing, with atomic precision, reactive molecules. Drexler insisted on the mechanical feasibility of such assemblers, whereas Smalley resisted the idea that such devices could be chemically constructed, because we do not have the required control. Underlying the debate, there are differences regarding the appropriate goals, methods, and theories of nanotechnology, and the appropriate way (...) of conceptualizing molecular assemblers. Not surprisingly, incommensurability emerges. In this paper, I assess the main features of the debate, the levels of the emerging incommensurability, and indicate one way in which the debate could be decided. (shrink)