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)

This introduction provides background information on the emerging field of nanotechnology and its ethical dimensions. After defining nanotechnology and briefly discussing its status as a discipline, about which there exists a meta-controversy, this introduction turns to a discussion of the status of nanoethics and lays out particular issues of concern in the field, both current and emerging.

L’article procède à un cheminement en quatre étapes : la première traite de la question de la mesure économique des productions nanométriques, dans une dynamique de filière et de convergence multidisciplinaire, champ d’étude de la méso-économie ; la seconde fait référence aux origines de l’approche mercantiliste de l’économie et à ses conséquences sur l’économie politique des matériaux avancés, procédés et services du domaine des nanotechnologies et matériaux avancés manufacturés ; la troisième étape recherchera les points d’appui sur lesquels l’économie politique (...) fait porter ses efforts pour développer la production et les échanges induits par les nanosciences et techniques en s’appuyant sur deux exemples ; la quatrième et dernière étape examine les barrières réelles au développement économique induit par les nanotechnologies, telles que les conflits d’intérêts entre acteurs autour de la question de la traçabilité les ont progressivement révélées dans les dialogues entre parties prenantes. (shrink)

A short overview, written for a primarily scientific audience, of how conceptual analysis and philosophy of science can assist in nanoscience research.

In this paper we present findings from an experiment involving both scientists working at the nanoscale and philosophers interested in this emerging field of research. Early career scientists working at the nanoscale were asked to read, discuss and debate two examples of philosophy of science that had been written with a specific focus on nanoscale science and technology. The papers that our participating scientists were asked to read were one by Jan Schmidt and one by George Khushf. These papers are (...) interesting for comparative discussion because although both draw on similar cases to make their arguments, Schmidt argues that nanotechnology represents a new form of reductionism, while Khushf argues that the field represents a shift towards more systems-based approaches of understanding and acting. The initial aim of this experimental exercise was both to create a space for discussion and reflection, and to investigate the scientific literacy of emerging works in the philosophy of nanoscience. Interestingly, interdisciplinary interaction during the exercise saw unexpected topics of interest and discussion emerge. In discussing the two articles, the scientists participating in our exercise highlighted a range of questions that not only related to the scientific content of the philosophers' arguments, but also to the way in which they conducted and presented their research. This exercise demonstrates the added value and richness that can come from interdisciplinary interactions across the social and natural sciences and from iterative discussions across theory and practice, especially when focused on emerging fields of research such as that of nanoscience and technology. (shrink)

During the education of scientists at the university level the students become more and more specialized. The specialization of the students is a consequence of the scientific research becoming specialized as well. In the interdisciplinary field of nanoscience the importance of specialization is also emphasized throughout the education. Being an interdisciplinary field of study the specialization in this area is not focused on scientific disciplines, but on the different branches of the research. Historically ethics has not been a priority in (...) science education, however, in recent years the importance of such teachings has been highly recognize especially in medicine, biotechnology and engineering. The rapid development, the many new and unknown areas and the highly specialized focus of nanotechnology suggest the importance of having ethically competent researchers. In this article the importance of ethical competence in nanoscience research is argued for by an example of a dilemma that could occur in a research project. The dilemma is analyzed using two different ethical views, generating two different choices for action. It is seen that the dilemma can have more than one solution and that ethical competence can help in justifying the choice of solution in a specific situation. Furthermore it is suggested that a way to reach this competence is through education in ethics incorporated into the nanoscience education curriculum. (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)

There have been several conscious efforts made by different stakeholders in the area of nanoscience and nanotechnology to increase the awareness of social and ethical issues (SEI) among its practitioners. But so far, little has been done at the laboratory level to integrate a SEI component into the laboratory orientation schedule of practitioners. Since the laboratory serves as the locus of activities of the scientific community, it is important to introduce SEI there to stimulate thinking and discussion of SEI among (...) practitioners, which would eventually contribute toward the responsible development of this technology. In this article, through an example (at the Cornell NanoScale Science and Technology Facility (CNF), practitioners of which represent a section of the nano researchers’ community in the USA), it is shown how a SEI component can be incorporated into the laboratory orientation schedule of the practitioners from diverse disciplinary and institutional backgrounds. Results show that, at CNF, the practitioners enjoyed the discussion since most of them learned about SEI for the first time in their professional career. At the same time, some of them were also knowledgeable about SEI and contributed to the debates. Moreover, the SEI orientation had significant positive impact on the scientific community enabling them to self-reflect upon their own research and its implications for the wider society. This article also describes the efforts that were undertaken to disseminate this form of SEI orientation to other 13 USA universities within the National Nanotechnology Infrastructure Network (NNIN, one of the biggest networks funded from National Science Foundation for Nanotechnology research, of which CNF is a part). As a result of this effort, most of the NNIN sites have already started or were in the process of integrating a SEI component into their nanofabrication laboratories to make their users aware of SEI, ensuring eventual robust socio-technical integration in the NNIN laboratories. In the future, this form of SEI orientation can also be disseminated to other nanofabrication laboratories in the USA. (shrink)

Nanotechnology as an emerging field is strongly related to visionary prospects which are disposed to reappear as dystopian concerns. As long as nanotechnology does not provide reliable criteria for assessing these worries as rational or as irrational they remain a challenge for ethical reflection. Given this underdetermination, many nanovisions and their corresponding concerns should therefore be considered as “arational.” For that reason, a “constructivist” stance is endorsed which does not seek to take part in discussions as to how ethicists should (...) cope with controversial worries, but tries to observe how concerns are managed by different social actors. This perspective allows us to remodel some concerns such as “grey goo” not solely as a societal reaction, but also as challenging and irritating factors. As such they potentially initiate two different processes simultaneously: a differentiation in terms of demarcating science from non-science on the one hand, and a rationalization of concerns on the other. Analyzing these processes empirically allows to reconstruct how “arational” concerns are socially made rational or, on the contrary, irrational. (shrink)

Imagine your body is populated by billions of respirocytes capable of delivering 236 times more oxygen than your natural red blood cells. These mechanical, micron sized spheres are appropriately programmed by your physician to meet your personal requirements, be it the treatment of anemia or the enhancement of your physical abilities. Robert Freitas’ vision of such artificial blood cells comprised of nanometer-scale components was published in 1998 in a peer-reviewed medical journal, and was the first medical nanorobot design paper to (...) be published.The fact that this proposal for a future blood substitute was accepted as worthy of publication in a scientific journal, despite the inventor's explicit statement that such a device could not be built at the time, clouds the criteria upon which an informed opinion about the feasibility of such devices could be formed. In that respect, the idea of respirocytes formidably testifies to the current “blurring of fact and fiction” occurring in the field of nanotechnology. (shrink)

This article examines the visions on nanosciences and nanotechnologies (N&N) disseminated by a group of Brazilian scientists to legitimize this emergent field of research. For this purpose we analyzed reports on N&N published by the Journal of Science, edited daily by the Brazilian Society for the Progress of Science, from 2002 to 2007, covering the period in which the main events in domestic N&N research policy took place. Our analysis shows that researchers on N&N are spreading visions of progress, (...) efficiency and competitiveness related to the advances in this field, giving little attention to issues such as potential risks, and economic, social and ethical implications of these technologies. (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 focuses on the contribution of meta-regulation in responding to the regulatory needs of a field beset by significant uncertainties concerning risks, benefits and development trajectories and characterised by fast development. Meta-regulation allows regulators to address problems when they lack the resources or information needed to develop sound “discretion-limiting rules”; meta-regulators exploit the information advantages of those actors to be regulated by leveraging them into the task of regulating itself. The contribution of meta-regulation to the governance of nanotechnologies is (...) assessed in terms of responsibilisation. Responsibilisation is regarded as a pre -requisite for regulatory actors to internalise social values (such as consumer safety and occupational health) and to ensure that these values are built into regulatory practice. In order to explore the potential of responsibilisation, the Code of Conduct for Responsible Nanosciences and Nanotechnologies Research launched by the European Commission in 2008 is evaluated. The Code is a good case of meta-regulation that aims to steer the self-regulation of nanotechnological business and research organisations. The paper concludes that, while efforts were made on the part of meta-regulators and self-regulators to contribute to responsibilisation, important opportunities for responsibilisation such as dissemination and promotion of the Code, trust-building activities, and failure to provide rewards, incentives and stakeholder guidance were not taken up. In order to foster responsibilisation within the meta-regulatory instrument of the EC Code, a number of crucial activities to be undertaken by meta-regulators are recommended. (shrink)

The very existence of explicit techno-scientific controversies in the “nano” arena is often denied on behalf of a conception of science, risks, public engagement and responsibility which borders on a disembodied idealism and merits at least serious discussion. The recurrence of this view prompted us to clarify our position regarding our common field of research, in order to avoid being trapped in the seemingly clear divide between the universal and neutral pursuit of pure science, on the one hand, and on (...) the other hand the infinite variety of values and opinions that lead to the horrors throes of pure relativism. We therefore launched an internal trans-disciplinary project, in order to overhaul the premises underpinning both this idealistic standpoint and our own work, and to find a better definition of our approach to the exploration of the real policy implications of NST research initiatives. Indeed, the debates surrounding NST clearly have wider implications for the examination of issues of Science, Technology and Society as a whole. A first step in this clarification process was taken in Paris, at the conference which has now been published in this issue of Foundations of Chemistry. We further develop it in this paper, in the hope that it will contribute to the joint construction of a better nano-future. (shrink)

Printbegrænsninger: Der kan printes kapitelvis.

It is now more than a decade since the release of the Royal Society and Royal Academy of Engineering’s seminal report on nanosciences and nanotechnologies. The report, for the first time, brought together the spectrum of scientific and societal issues underpinning the emergence of the technology. In articulating 21 recommendations, the RA/RAEng provided the United Kingdom Government—and others—with an agenda on how they could, and should, deal with the disparate aspects of the technology. The report provides a baseline to (...) measure progress against. By focusing on the eight recommendations that dealt specifically with regulation and governance, I reflect on the extent, and nature, of this progress; identify key actors in shaping the evolving governance framework; and, importantly, distinguish areas where progress appears to have lagged. (shrink)

This paper proposes a new approach for analysing daily activities in a laboratory. The case study presented is an analysis of shop-talk around a microscope. In addition to the classical approaches, such as ethnomethodology and anthropology of science, I argue that a microsemiotic approach could be useful to better understand what is at stake. The semiotic approach I shall use here was proposed by a group of Belgian semioticians: Groupe μ. This semiotic approach leads to a constructivist point of view: (...) the meaning of a visual representation is progressively constructed and is very context-dependent. This semiotic approach is fruitful because it allows a very precise analysis of shop-talk recorded data, and gives a better account of the materiality of visual representations. (shrink)

Abstract: Science and emerging technologies should not be predominantly tasked with furnishing us with more sustainable societies. Continuous short-term technological bail outs without taking into account the longer socio-cultural incubation times required to transition to ‘weakly sustainable’ economies squander valuable resources and time. Emerging technologies need to be deployed strategically to buy time in order to have extended political, social and ethical discussions about the root-causes of unsustainable economies and minimize social disruptions on the path towards global sustainability. Keywords: Nanoscience; (...) nanotechnology; expanded materials design space; dematerialization; sustainability; permanent resource crises . (shrink)

UK science policy now includes ‘upstream public engagement’ as an element in the responsible development of nanotechnology. This paper explores different understandings of the term upstream engagement before discussing in more detail a laboratory-based collaboration between social science and nanoscience aimed at exploring the social dimensions of nanotechnology. The paper concludes that concern with defining what counts as ‘upstream’ can obscure more critical questions about how to make public, and therefore accountable, deliberations about the interrelated social and technical aspects of (...) nanoscience. (shrink)

The field of nanoscience and nanotechnology is expanding rapidly, promising great benefits for society in the form of better medicine, more efficient energy production, new types of materials, etc. Naturally, in order for the science and technology to live up to these promises, it is important to continue scientific research and development, but equally important is the ethical dimension. Giving attention to the social, ethical and legal aspects of the field, among others, will help in developing a fully responsible—and thereby (...) capable—science and technology. Nanoethics has emerged as a field concerned with such ethical issues related to nanoscience and nanotechnology. Even though this field is relatively new, a significant amount of literature has already been published. This paper focuses on three of the major issues which are discussed in the literature of nanoethics, and also points to a certain bias in this literature. Each quite different in nature, these issues are: (1) The naming and (2) the timing of and approach to the field, as well as (3) the issue of safety. As will be seen, these issues are almost exclusively discussed by ethicists, (throughout the article, the term’ethicist’ is used in a broad definition covering philosophers, social and political scientists as well as philosophers of science) thus having no direct influence on the work being carried out by scientists. One can argue, therefore, that this bias creates a distortion of the ethical debate, making it insufficient and misleading. Ultimately, this bias is caused by the lack of communication and collaboration between ethicists on the one hand, and nanoscientists on the other. Thus, an argument is made for the different disciplines to begin collaborating, so as to more effectively and responsibly develop the field of nanoscience. (shrink)

The aim of the article is to analyze the role played by popularization and training within nanotechnology as a mean to build a bridge between Nanosciences and Nanotechnologies; its applications in Biology, Biotechnology and Health Care Industry; and the object of study of Bioethics, mainly its general view. The article begins with a brief presentation of the basic concepts of Bioethics; of the paradigm of the relationship between science, technology and society; and of the contribution of general scientific and (...) technological knowledge to Bioethics. Afterwards, it analyzes in detail the interdisciplinary relationship of sciences and technologies with Bioethics and presents a brief conceptual exposition of Nanotechnology as well as its benefits and risks. The article ends by presenting some arguments in favor of considering popularization and training in Nanotechnology as a bridge towards bioethics. Finally, some general conclusions are sketched. (shrink)

This paper argues that narrative elements from the science fiction (SF) literary genre are used in the discourse of Nanoscience and Technology (NST) to bridge the gap between what is technically possible today and its inflated promises for the future. The argument is illustrated through a detailed discussion of two NST texts. The paper concludes by arguing that the use of SF narrative techniques poses serious problems to the development of a critical analysis of the ethical and social implications of (...) NST. (shrink)

The field of nanotechnology and nanoscience is growing rapidly in many areas of research, from electronics to biomedicine to material science. Carbon nanotubes are receiving a lot of attention in the research due to their unique properties and many possible applications. This new material is a good example of how nanotechnology provides us with new opportunities, but at the same time leaves us a lot of unknowns to deal with. In order to deal with the unknowns we need to consider (...) both the science and the ethics of the different applications of this novel material. Nanoethics is the study of the ethical issues in nanotechnology. It is a relatively new field of study and a lot of different methods have been suggested in this area. In this article a method is suggested combining an existing ethical theory with a practical approach in order to do a case study of the ethical considerations of using carbon nanotubes in biomedicine. For the case study to be of practical significance the scientific characteristics and properties of carbon nanotubes are reviewed to give the reader an overview of the research field. (shrink)

There is interest in more and better interaction between civil society and actors developing nanotechnologies, nano-materials and nano-enabled products: government agencies but also branch organizations in the chemical sector position civil society organizations (CSOs) as ‘voices of civil society’, and invite CSOs to participate in multistakeholder events. In such events, CSOs are expected to articulate societal needs, issues and values so that these can be taken up by actors with institutional roles and mandates to develop and embed newly emerging (...) class='Hi'>nanosciences and nanotechnologies (NEST). This article argues that such a division of moral labor between CSOs and nanotechnology actors is not productive to address NEST and its emerging societal issues. There is an assumption that societal issues are ‘out there’ and can be recognized by CSOs, while in fact, societal issues might co-evolve with new development trajectories and thus have to be discovered and articulated. More productive deliberation requires, ideally, overcoming the traditional division of moral labor between these two groups of actors: technology developers should also inquire into and articulate emerging societal issues, and CSOs should inquire into and reflect on actual development trajectories. In order to explore issues and repercussions that arise in such a repositioning, this article will discuss a bottom up experiment of such an interaction between a nanotechnology developer (DuPont) and a CSO (Environmental Defense Fund). Based on the empirical analysis of this bottom up experiment, tentative requirements will be developed for how joint inquiries between technology developers and CSOs can be realized on a larger scale in our society. (shrink)

While nanosciences and nanotechnologies appear as new concepts developed at the end of the twentieth century, we show that metallic nanoparticles have already been used since ancient times, in particular as colorant in the glass and ceramic industries. Moreover, a lot of natural nanomaterials are also present in the mineral, vegetal and animal worlds. Nevertheless, the breakthrough of nanotechnology has been permitted in the past few decades by the advent of apparatus allowing the manipulation and observation of the nanoworld. (...) Indeed, nowadays, nanomaterials and nanoparticles are used for many applications in our daily life, such as in the fields of electronics, catalysis, optics, biology, and medicine. This article presents an overview about nanotechnologies, with applications from ancient times till the present. (shrink)

This analysis of Mexico’s nanotechnology policies utilizes indicators developed by the Organization for Economic Co-operation and Development, which in 2008 conducted a pilot survey comparing the nanotechnology policies of 24 countries. In this paper, we apply the same questionnaire to the Mexican case, adding business information derived from the National Institute of Statistics and Geography survey on nanotechnologies, also an OECD instrument.

Lately, nanotechnology has become one of the main topics in the debates regarding what has been called the _Next Industrial Revolution_ within what are known as _emergent technologies_. This paper contains a comparative analysis of the different philosophical groundings, arguments and principles invoked in the official ethical approaches proposed by each of two of the main Western communities. By _official ethical approaches_ or _official positions_ we mean the opinions officially expressed by the government institutions about how ethical considerations prompted by (...) nanotechnologies should be tackled. The analysis is based, then, on the official points of view, expressed through two documents, namely two official releases issued by governmental offices or institutions in both communities, Europe and the United States of America, and considered by the authors as representative of the official opinions of the governmental institutions in each society. (shrink)

Nanotechnology and nanosciences have recently gained tremendous attention and funding, from multiple entities and directions. In the last 10 years the funding for nanotechnology research has increased by orders of magnitude. An important part that has also gained parallel attention is the societal and ethical impact of nanotechnology and the possible consequences of its products and processes on human life and welfare. Multiple thinkers and philosophers wrote about both negative and positive effects of nanotechnology on humans and societies. The (...) literature has a considerable amount of views about nanotechnology that range from calling for the abandonment and blockage of all efforts in that direction to complete support and encouragement in hopes that nanotechnology will be the next big jump in ameliorating human life and welfare. However, amidst all this hype about the ethics of nanotechnology, relatively less efforts and resources can be found in the literature to help engineering professionals and educators, and to provide practical methods and techniques for teaching ethics of nanotechnology and relating the technical side of it to the societal and human aspect. The purpose of this paper is to introduce strategies and ideas for teaching ethics of nanotechnology in engineering in relation to engineering codes of ethics. The paper is neither a new philosophical view about ethics of nanotechnology nor a discussion of the ethical dimensions of nanotechnology. This is an attempt to help educators and professionals by answering the question of how to incorporate ethics of nanotechnology in the educational process and practice of engineering and what is critical for the students and professionals to know in that regard. The contents of the presented strategies and ideas focus on the practical aspects of ethical issues related to nanotechnology and its societal impact. It also builds a relation between these issues and engineering codes of ethics. The pedagogical components of the strategies are based on best-practices to produce independent life-long self-learners and critical thinkers. These strategies and ideas can be incorporated as a whole or in part, in the engineering curriculum, to raise awareness of the ethical issues related to nanotechnology, improve the level of professionalism among engineering graduates, and apply ABET criteria. It can also be used in the way of professional development and continuing education courses to benefit professional engineers. Educators and institutions are welcome to use these strategies, a modified version, or even a further developed version of it, that suits their needs and circumstances. (shrink)

This article explores the crucial moments of scientists’ research activities when they decide to shift to a radical new domain or to perpetuate a project. We introduce what we have called the “respiration model” which describes and analyses key cognitive components which occur in this complex process. Respiration either privileges epistemic expectations which are rooted in socio-cognitive metrics of “concentration” or in a functionality-multiple horizon context which we refer to as “extension”. The respiration model accords particular attention to the elements (...) curiosity and synergy in science. (shrink)

Nanoscience has enabled the understanding of organisation of the atomic and molecular world. Due to the unique chemical, electronic and magnetic properties nanomaterials have wide applications in the chemical, manufacturing, medical sector etc., Single walled carbon nanotubes, buckyballs, ZnSe quantum dots, TiO 2 nanoparticle based products are nearing commercialisation. Research is on-going worldwide on suitable delivery systems for nanomaterial based drugs. Nanomaterials are highly reactive in biological systems due to the large surface area. While the benefits of nanomaterials are evident (...) there are studies which indicate the potential risk to biological systems. Substances known to be harmless in bulk can be potentially toxic in certain fibrous and nanoparticle form. Risk assessment studies with nanomaterials largely focus on mouse models. There are very few studies on their effects on aquatic species and plants which form the largest in the productivity chain with respect to the ecological pyramid. This study reviews the research done worldwide in the area of risk assessment of nanomaterials, particularly the effects on aquatic and plant systems. Risk assessment is the foundation for regulatory decision making. A general comparison of the regulatory regime in nanotechnology is performed to understand the extent of development. (shrink)

Nanotechnologies and nanoscience have generated an unprecedented global research and development race involving dozens of countries. The understanding of associated environmental, ethical, and societal implications lags far behind the science and technology. Consequently, it is critical to consider both what is known and what is unknown to offer a kernel that future work can be added to. The challenges presented by nanotechnologies are discussed. Some initial solutions such as self-regulation and borrowing techniques and tools from other fields are accompanied by (...) a call for further research. (shrink)

This paper starts by looking at the coincidence of surprising behavior on the nanolevel in both matter and simulation. It uses this coincidence to argue that the simulation approach opens up a pragmatic mode of understanding oriented toward design rules and based on a new instrumental access to complex models. Calculations, and their variation by means of explorative numerical experimentation and visualization, can give a feeling for a model's behavior and the ability to control phenomena, even if the model itself (...) remains epistemically opaque. Thus, the investigation of simulation in nanoscience provides a good example of how science is adapting to a new instrument: computer simulation. (shrink)

Should philosophers of science be paying attention to developments in "nanoscience"? Undoubtedly, it is too early to tell for sure. The goal of this paper is to take a preliminary look. In particular, I look at the use of computational models in the study of nano-sized solid-state materials. What I find is that there are features of these models that appear on their face to be at odds with some basic philosophical intuitions about the relationships between different theories and between (...) theories and their models. My conclusion is that developments in nanoscience are not an unlikely place for novel insights in the philosophy of science to emerge. (shrink)

The article addresses the issue of dynamics of science, in particular of new sciences born in twentieth century and developed after the Second World War (information science, materials science, life science). The article develops the notion of search regime as an abstract characterization of dynamic patterns, based on three dimensions: the rate of growth, the degree of internal diversity of science and the associated dynamics (convergent vs. proliferating), and the nature of complementarity. The article offers a conceptual discussion for the (...) argument that new sciences follow a different pattern than established sciences and presents preliminary evidence drawn from original data in particle physics, computer science and nanoscience. (shrink)

Issues of responsibility in the world of nanotechnology are becoming explicit with the emergence of a discourse on ‘responsible development’ of nanoscience and nanotechnologies. Much of this discourse centres on the ambivalences of nanotechnology and of promising technology in general. Actors must find means of dealing with these ambivalences. Actors’ actions and responses to ambivalence are shaped by their position and context, along with strategic games they are involved in, together with other actors. A number of interviews were conducted with (...) industrial actors with the aim of uncovering their ethical stances towards responsible development of nanotechnology. The data shows that standard repertoires of justification of nanotechnological development were used. Thus, the industrial actors fell back on their position and associated responsibilities. Such responses reinforce a division of moral labour in which industrial actors and scientists can focus on the progress of science and technology, while other actors, such as NGOs, are expected to take care of broader considerations, such as ethical and social issues. (shrink)

ABSTRACT I propose a division of the literature on natural kinds into metaphysical worries, semantic worries, and methodological worries. I argue that the latter set of worries, which concern how classification influences scientific practices, should occupy centre stage in philosophy of science discussions about natural kinds. I apply this methodological framework to the problems of classifying chemical species and nanomaterials. I show that classification in nanoscience differs from classification in chemistry because the latter relies heavily on compositional identity, whereas the (...) former must consider additional properties, namely, size, shape, and surface chemistry. I use this difference to argue for a scale-dependent theory of scientific classification. _1_ Introduction _2_ The Methodological Problem of Kinds _3_ Chemical Kindhood: Reactivity, Microstructure, and the Structure–Property Paradigm _4_ Scale-Dependence and Nanoscale Kinds _5_ Conclusion. (shrink)

Les premiers spécialistes, tant en sciences humaines qu’en physique et en chimie, se sont vite rendus à l’idée selon laquelle chacun pourrait avoir sa définition des nanotechnologies. Ils s’inscrivent ainsi dans ce que nous considérons comme une culture des « faits alternatifs » plutôt répandue dans les sciences contemporaines. Ce texte est une note critique autour de la difficulté à définir précisément ce qu’il faut entendre par nanosciences et nanotechnologies. Dans la première partie, nous faisons ressortir la multiplication des (...) définitions, liée aux luttes économiques, aux enjeux stratégiques et aux intérêts hétérogènes des acteurs. Puis, nous cherchons à dépasser ce relativisme en nous focalisant sur les outils qui permettent l’accès à l’échelle nanométrique et sur les changements de propriétés inhérents à l’échelle quantique. (shrink)

Fabriquer un être humain supérieur, artificiel, voire immortel, dont les imperfections seraient réparées et les capacités améliorées. Telle est l'ambition du mouvement transhumaniste, qui prévoit le dépassement de l'humanité grâce à la technique et l'avènement prochain d'un "homme augmenté" façonné par les biotechnologies, les nanosciences, la génétique. Avec le risque de voir se développer une sous-humanité de plus en plus dépendante de technologies qui modèleront son corps et son cerveau, ses perceptions et ses relations aux autres. Non pas l'"homme (...) nouveau" des révolutionnaires, mais l'homme-machine du capitalisme. Bien que le discours officiel, en France, résiste encore à cette idéologie, le projet technoscientifique avance discrètement. Qui impulse ces recherches? Comment se développent-elles dans les champs médicaux, militaires et sportifs? Comment les débats démocratiques sont-ils éludés? Et comment faire face à des évolutions qui ne feront que renforcer les inégalités? Surtout, quel être humain va naître de ces profondes mutations, de ces expérimentations brutales et hasardeuses sur notre espèce, dont l'Homo sapiens ne sortira pas indemne? (shrink)

This paper follows the history of an object. The purpose of doing so is to come to terms with a distinctive kind of research object – which we are calling a ‘test object’ – as well as to chronicle a significant line of research and technology development associated with the broader nanoscience/nanotechnology movement. A test object is one of a family of epistemic things that makes up the material culture of laboratory science. Depending upon the case, it can have variable (...) shadings of practical, mathematical and epistemic significance. Clear cases of test objects have highly regular and reproducible visible properties that can be used for testing instruments and training novices. The test object featured in this paper is the silicon 7×7, a particular surface configuration of silicon atoms. Research on this object over a period of several decades has been closely bound up with the development of novel instruments for visualizing atomic structures. Despite having little direct commercial value, the Si 7×7 also has been a focal object for the formation of a research community bridging industry and academia. It exhibits a complex structure that became a sustained focus of observation and modelling. Our study follows shifts in the epistemic status of the Si 7×7, and uses it to re-examine familiar conceptions of representation and observation in the history, philosophy and social study of science. (shrink)

There is currently a strong focus on responsible research in relation to the development of nanoscience and nanotechnology. This study presents a series of conversations with nanoresearchers, with the ‘European Commission recommendation on a code of conduct for responsible nanosciences and nanotechnologies research’ (EC-CoC) as its point of departure. Six types of reactions to the document are developed, illustrating the diversity existing within the scientific community in responses towards this kind of new approaches to governance. Three broad notions of (...) responsible nanoresearch are presented. The article concludes by arguing that while the suggestion put forward in the EC-CoC brings the concept of responsible nanoresearch a long way, one crucial element is to be wanted, namely responsible nanoresearch as increased awareness of moral choices. (shrink)

There might not be a specific nano-ethics, but there definitely is an ethics of new & emerging science and technology (NEST), with characteristic tropes and patterns of moral argumentation. Ethical discussion in and around nanoscience and technology reflects such NEST-ethics. We offer an inventory of the arguments, and show patterns in their evolution, in arenas full of proponents and opponents. We also show that there are some nano-specific issues: in how size matters, and when agency is delegated to smart devices. (...) Our overall approach is a pragmatist ethics, and we conclude that struggle (and learning) might be more productive than models emphasizing consensus. (shrink)

This paper aims to contribute to the expanding discourse on inter- and transdisciplinarity. Referring to well-established distinctions in philosophy of science, the paper argues in favor of a plurality of four different dimensions: Interdisciplinarity with regard to objects, knowledge/theories, methods/practices, and further, problem perception/problem solving. Different philosophical thought traditions can be related to these distinguishable meanings. The philosophical framework of the four different dimensions will be illustrated by some of the most popular examples of research programs that are labeled interdisciplinary (...) : nanoresearch/nanoscience/nanotechnology, complex systems theory/chaos theory, biomimicry/bionics, and technology assessment/sustainability research. Thus, a minimal philosophy of science is required to understand and foster inter- and transdisciplinarity. (shrink)

Many believe that nanotechnology will be disruptive to our society. Presumably, this means that some people and even whole industries will be undermined by technological developments that nanoscience makes possible. This, in turn, implies that we should anticipate potential workforce disruptions, mitigate in advance social problems likely to arise, and work to fairly distribute the future benefits of nanotechnology. This general, somewhat vague sense of disruption, is very difficult to specify – what will it entail? And how can we responsibly (...) anticipate and mitigate any problems? We can't even clearly state what the problems are anticipated to be. In fact, when we move from sweeping policy statements to more concrete accounts, nanotechnology seems to bifurcate into two divergent streams: one is fairly continuous with current developments, extending extant science in a quantitative way; the other is radically new, and includes science fiction-like dreams of molecular manufacturing and assemblers, with their utopian scenarios of absolute plenty. In these cases, “disruption” takes on the valence of Huxley's brave new world. (shrink)

This paper develops a fourth model of public engagement with science, grounded in the principle of nurturing scientific agency through participatory bioethics. It argues that social media is an effective device through which to enable such engagement, as it has the capacity to empower users and transforms audiences into co-producers of knowledge, rather than consumers of content. Social media also fosters greater engagement with the political and legal implications of science, thus promoting the value of scientific citizenship. This argument is (...) explored by considering the case of nanoscience and nanotechnology, as an exemplar for how emerging technologies may be handled by the scientific community and science policymakers. (shrink)