The paper illustrates how organic chemists dramatically altered their practices in the middle part of the twentieth century through the adoption of analytical instrumentation — such as ultraviolet and infrared absorption spectroscopy and nuclear magnetic resonance spectroscopy — through which the difficult process of structure determination for small molecules became routine. Changes in practice were manifested in two ways: in the use of these instruments in the development of ‘rule-based’ theories; and in an increased focus on synthesis, at the expense (...) of chemical analysis. These rule-based theories took the form of generalizations relating structure to chemical and physical properties, as measured by instrumentation. This ‘Instrumental Revolution’ in organic chemistry was two-fold: encompassing an embrace of new tools that provided unprecedented access to structures, and a new way of thinking about molecules and their reactivity in terms of shape and structure. These practices suggest the possibility of a change in the ontological status of chemical structures, brought about by the regular use of instruments. The career of Robert Burns Woodward provides the central historical examples for the paper. Woodward was an organic chemist at Harvard from 1937 until the time of his death. In 1965, he won the Nobel Prize in Chemistry. (shrink)

A layered interpretation of the history of chemistry is discussed through chemical revolutions. A chemical revolution mainly by emplacement, instead of replacement, procedures were identified by: a radical reinterpretation of existing thought recognized by contemporaries themselves, which means the appearance of new concepts and the arrival of new theories; the use of new instruments changed the way in which its practitioners looked and worked in the world and through exemplars, new entities were discovered or incorporated; the opening of new subdisciplines, (...) which produced, separated scientific communities. The fourth chemical revolution, fundamentally characterized by the incorporation of new instruments in chemical practices is discussed. (shrink)

Contrary to the assumptions of empiricist philosophies of science, the theory-laden character of data will not imply the inherent failure (subjectivity, circularity, or rationalization) of instruments to expose nature's secrets. The success of instruments is credited to scientists' capacity to create artificial technological analogs to familiar physical systems. The design of absorption spectrometers illustrates the point: Progress in designing many modern instruments is generated by analogically projecting theoretical insights from known physical systems to unknown terrain. An experimental realism is defended.

Despite its proliferation in technology studies, the concept of “path dependence” has scarcely been applied to epistemology. In this essay, I investigate path dependence in the production of scientific knowledge, first, by considering Kuhn's scattered remarks that lend support to a path-dependence thesis (Section I) and second by developing and criticising Kuhn's embryonic account (Sections II and III). I examine a case from high-energy physics that brings the path-dependent nature of scientific knowledge to the fore and I pay attention to (...) two sources of path dependence—“theoretical” and “instrumental”. The latter source is particularly important in “big science”. I ask in Section IV whether path dependence in scientific knowledge can lead to circumstances like those in the technological field, in which a theory can come to dominate a scientific speciality even though it is inferior to alternatives. In Section V, I ask what implications my thesis has for science policy. (shrink)

Crucial to the establishment of a scientific discipline is a body of knowledge organized around a set of instruments, interpretive techniques, and regimes of training in their application. In this paper, we trace the involvement of scientists and engineers at Varian Associates in the development of nuclear magnetic resonance spectrometers from the first demonstrations of the NMR phenomenon in 1946 to the definitive takeoff of NMR as a chemical discipline by the mid-1960s. We examine the role of Varian scientists in (...) constructing several models of NMR instruments for research scientists in the 1950s and the Varian efforts to influence the adoption of NMR as a standard tool for chemical analysis through Varian-supported publications, participation in scientific meetings, collaborations with academic chemists, workshops, and postdoctoral fellowships. Special attention is devoted to the development of the Varian A-60, the first commercial NMR instrument intended for the broadly trained chemist rather than a custom-built tool for the research specialist. Drawing on an examination of the use-rate of NMR instruments in chemical literature, the assessment of NMR in the chemical review literature by practitioners, and indicators of the establishment of a suitable funding environment for the growth of physics-based scientific instrumentation in the post-Sputnik era, we argue that the establishment of NMR as a discipline coincided with the adoption of the A-60 in the mid-1960s. During the period of our study, Varian Associates was a primary military contractor. This paper is intended to contribute to recent interest in the relation of military fundingto scientific enterprise during the Cold War and to the larger question of university-industry interactions in the growth of knowledge. (shrink)

The article takes the term "technoscience" literally and investigates a conception of science that takes it not only as practice, but as production in the sense of a material labor process. It will explore in particular the material connection between science and ordinary production. It will furthermore examine how the historical development of science as a social enterprise was shaped by its technoscientific character. In this context, in an excursus, the prevailing notion will be questioned that social relations must be (...) conceived of as pure interactions. Finally, the article will go into the relationship between the epistemic dimension of science and its technoscientific character. (shrink)

SummaryThis essay explains why and how nineteenth-century chemists sought to stabilize the melting and boiling points of organic substances as reliable characteristics of identity and purity and how, by the end of the century, they established these values as ‘Constants of Nature’. Melting and boiling points as characteristic values emerge from this study as products of laboratory standardization, developed by chemists in their struggle to classify, understand and control organic nature. A major argument here concerns the role played by the (...) introduction of organic synthesis in driving these changes. Synthetic organic chemistry vastly increased the number of known organic substances, precipitating the chemical identity crisis of my title. Successful natural product synthesis, moreover, depended on chemists’ ability to demonstrate the absolute identity of synthetic product and natural target – something late nineteenth-century chemists eventually achieved by making reliable, replicable melting and boiling point measurements. In the period before the establishment of national standards laboratories, chemists and scientific glassblowers worked together to standardize melting and boiling points as physical constants, such collaborations highlighting the essential importance of chemical glassware and glassblowing skill in the development of nineteenth-century organic chemistry. (shrink)