Thomas Samuel Kuhn

Britannica Concise Encyclopedia: Thomas Samuel Kuhn

(born July 18, 1922, Cincinnati, Ohio, U.S. — died June 17, 1996, Cambridge, Mass.) U.S. historian and philosopher of science. He taught at Berkeley (1956 – 64), Princeton (1964 – 79), and the Massachusetts Institute of Technology (1979 – 91). In his highly influential work The Structure of Scientific Revolutions (1962), he questioned the previously accepted view of scientific progress as a gradual accumulation of knowledge based on universally valid experimental methods and results, claiming that progress was often achieved by far-reaching "paradigm shifts." His other works include The Copernican Revolution (1957), The Essential Tension (1977), and Black-Body Theory and the Quantum Discontinuity (1978).

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Thomas Samuel Kuhn (1922-1996) was an American historian and philosopher of science. He found that basic ideas about how nature should be studied were dogmatically accepted in normal science, increasingly questioned, and overthrown during scientific revolutions.

Born in Cincinnati, Ohio, in 1922, Thomas Kuhn was trained as a physicist but became an educator after receiving his Ph.D. in physics from Harvard in 1949. He taught as an assistant professor of the history of science at Harvard from 1952 to 1957, as a professor of the history of science at Berkeley (California) from 1958 to 1964, as a professor of the history of science at Princeton from 1964 to 1979, as a professor of philosophy and the history of science at Massachusetts Institute of Technology (MIT) from 1979 to 1983, and finally, Laurence Rockefeller professor of philosophy at MIT from 1983 to 1991. A member of many professional organizations, he was president of the History of Science Society from 1968 to 1970. He received the Howard T. Behrman award at Princeton in 1977 and the George Sarton medal from the History of Science Society in 1982.

Kuhn's scholarly achievements were many. He held positions as a Lowell lecturer in 1951, Guggenheim fellow from 1954 to 1955, fellow of the Center for Advanced Studies in Behavioral Science from 1958 to 1959, director of the Sources for the History of Quantum Physics Project from 1961 to 1964, director of the Social Science Research Council from 1964 to 1967, director of the program for history and philosophy of science at Princeton from 1967 to 1972, member of the Institute for Advanced Study at Princeton from 1972 to 1979, and member of the Assembly for Behavioral and Social Science in 1980.

Kuhn was best known for debunking the common belief that science develops by the accumulation of individual discoveries. In the summer of 1947 something happened that shattered the image of science he had received as a physicist. He was asked to interrupt his doctorate physics project to lecture on the origins of Newton's physics. Predecessors of Newton such as Galileo and Descartes were raised within the Aristotelian scientific tradition. Kuhn was shocked to find in Aristotle's physics precious little a Newtonian could agree with or even make sense of. He asked himself how Aristotle, so brilliant on other topics, could be so confused about motion and why his views on motion were taken so seriously by later generations. One hot summer day while reading Aristotle, Kuhn said he he had a brainstorm. "I gazed abstractly out the window of my room. Suddenly the fragments in my head sorted themselves out in a new way, and fell into place together, my jaw dropped," as reported by his friend and admirer, Malcolm Gladwell, in the July 8th issue of The New Yorker. He realized that he had been misreading Aristotle by assuming a Newtonian point of view. Taught that science progresses cumulatively, he had sought to find what Aristotle contributed to Newton's mechanics. This effort was wrong-headed, because the two men had basically different ways of approaching the study of motion.

For example, Aristotle's interest in change in general led him to regard motion as a change of state, whereas Newton's interest in elementary particles, thought to be in continuous motion, led him to regard motion as a state. That continuous motion requires explanation by appeal to some force keeping it in motion was taken as obvious by Aristotle. But Newton thought that continued motion at a certain speed needed no explanation in terms of forces. Newton invoked the gravitational force to explain acceleration and advanced a law that an object in motion remains in motion unless acted upon by an external force.

This discovery turned Kuhn's interest from physics to the history of physics and eventually to the bearing of the history of science on philosophy of science. His working hypothesis that reading a historical text requires sensitivity to changes in meaning provided new insight into the work of such great physicists as Boyle, Lavoisier, Dalton, Boltzmann, and Plank. This hypothesis was a generalization of his finding that Aristotle and Newton worked on different research projects with different starting points which eventuated in different meanings for basic terms such as "motion" or "force." Most people probably think that science has exhibited a steady accumulation of knowledge. But Kuhn's study of the history of physics showed this belief to be false for the simple reason that different research traditions have different basic views that are in conflict. Scientists of historically successive traditions differ about what phenomena ought to be included in their studies, about the nature of the phenomena about what aspects of the phenomena do or do not need explanation, and even about what counts as a good explanation or a plausible hypothesis or a rigorous test of theory.

Especially striking to Kuhn was the fact that scientists rarely argued explicitly about these basic research decisions. Scientific theories were popularly viewed as based entirely on inferences from observational evidence. But no amount of experimental testing can dictate these decisions because they are logically prior to testing by their nature. What, if not observations, explains the consensus of a community of scientists within the same tradition at a given time? Kuhn boldly conjectured that they must share common commitments, not based on observation or logic alone, in which these matters are implicitly settled. Most scientific practice is a complex mopping-up operation, based on group commitments, which extends the implications of the most recent theoretical breakthrough. Here, at last, was the concept for which Kuhn had been searching: the concept of normal science taking for granted a paradigm, the locus of shared commitments.

In 1962 Kuhn published his landmark book on scientific revolutions, which was eventually translated into 16 languages and sold over a million copies. He coined the term "paradigm" to refer to accepted achievements such as Newton's Principia which contain examples of good scientific practice. These examples include law, theory, application, and instrumentation. They function as models for further work. The result is a coherent research tradition. In his postscript to the second edition, Kuhn pointed out the two senses of "paradigm" used in his book. In the narrow sense, it is one or more achievement wherein scientists find examples of the kind of work they wish to emulate, called "exemplars." In the broad sense it is the shared body of preconceptions controlling the expectations of scientists, called a "disciplinary matrix." Persistent use of exemplars as models gives rise to a disciplinary matrix that determines the problems selected for study and the sorts of answers acceptable to the scientific community.

Using the paradigm concept, Kuhn developed a theory of scientific change. A tradition is pre-scientific if it has no paradigm. A scientific tradition typically passes through a sequence of normal science-crisis-revolution-new normal science. Normal science is puzzle-solving governed by a paradigm accepted uncritically. Difficulties are brushed aside and blamed on the failure of the scientist to extend the paradigm properly. A crisis begins when scientists view these difficulties as stemming from their paradigm, not themselves. If the crisis is not resolved, a revolution sets in, but the old paradigm is not given up until it can be replaced by a new one. Then new normal science begins and the cycle is repeated. Just when to accept a new paradigm and when to stick to the old one is a matter not subject to proof, although good reasons can be adduced for both options. Scientific rationality is not found in rules of scientific method but in the collective judgment of the scientific community. We must give up the notion that science progresses cumulatively toward the truth about reality; after a revolution it merely replaces one way of seeing the world with another.

Kuhn's theory of scientific change was the most widely influential philosophy of science since that of his mentor, Sir Karl Popper. Kuhn's claims were much discussed by scientists, who generally accepted them; by sociologists, who took them to elucidate the subculture of scientists; by historians, who found cases of scientific change not fitting his model; and by philosophers, who generally abhorred Kuhn's historical relativism about knowledge but accepted the need for their theories of science to do justice to its history. Kuhn was often perturbed by those who sought to - in his view - apply his ideas to areas where it was inappropriate. "I'm much fonder of my critics than my fans," he often said, according to Gladwell's New Yorker article. Indeed, he even tried in later years to replace the term "paradigm" - which he felt was being overused - with "exemplar." Kuhn died June 17, 1996, at his home in Cambridge, Massachusetts. Notwithstanding the tendency of some to misapply his theories, history will show that Kuhn indeed transformed the image of science by making it exciting and emphasizing that it is a social process in addition to being a rational one.

Thomas Samuel Kuhn
Western Philosophy 20th-century philosophy
Full name	Thomas Samuel Kuhn
Born	July 18, 1922(1922-07-18) Cincinnati, Ohio
Died	June 17, 1996 (aged 73)
School/tradition	Analytic
Main interests	Philosophy of science
Notable ideas	Paradigm shift Incommensurability "Normal" science
Influenced by Immanuel Kant · Alexandre Koyré Michael Polanyi Gaston Bachelard · Jean Piaget Bertrand Russell · Karl Popper
Influenced Virtually all philosophy of science after 1962 (including Paul Feyerabend)

Life

Thomas Kuhn was born in Cincinnati, Ohio to Samuel L. Kuhn, an industrial engineer, and Minette Stroock Kuhn. He obtained his B.S. degree in physics from Harvard University in 1943, and M.S. and Ph.D. degrees in physics in 1946 and 1949, respectively. As he states in the first few pages of the preface to the second edition of The Structure of Scientific Revolutions, his three years of total academic freedom as a Harvard Junior Fellow were crucial in allowing him to switch from physics to the history (and philosophy) of science. He later taught a course in the history of science at Harvard from 1948 until 1956 at the suggestion of university president James Conant. After leaving Harvard, Kuhn taught at the University of California, Berkeley, in both the philosophy department and the history department, being named Professor of the History of Science in 1961. At Berkeley, he wrote and published (in 1962) his best known and most influential work:^[1] The Structure of Scientific Revolutions. In 1964, he joined Princeton University as the M. Taylor Pyne Professor of Philosophy and History of Science. In 1979, he joined the Massachusetts Institute of Technology (MIT) as the Laurance S. Rockefeller Professor of Philosophy, remaining there until 1991. Kuhn interviewed and taped Danish physicist Niels Bohr the day before Bohr's death. The recording contains the last words of Niels Bohr caught on tape.^{[citation needed]} In 1994, Kuhn was diagnosed with cancer of the bronchial tubes, of which he died in 1996.

Thomas Kuhn was married twice, first to Kathryn Muhs (with whom he had three children) and later to Jehane Barton (Jehane R. Kuhn).

The Structure of Scientific Revolutions

Main article: The Structure of Scientific Revolutions

The Structure of Scientific Revolutions (SSR) was originally printed as an article in the International Encyclopedia of Unified Science, published by the logical positivists of the Vienna Circle. In this book, Kuhn argued that science does not progress via a linear accumulation of new knowledge, but undergoes periodic revolutions, also called "paradigm shifts" (although he did not coin the phrase),^[2] in which the nature of scientific inquiry within a particular field is abruptly transformed. In general, science is broken up into three distinct stages. Prescience, which lacks a central paradigm, comes first. This is followed by "normal science", when scientists attempt to enlarge the central paradigm by "puzzle-solving". Thus, the failure of a result to conform to the paradigm is seen not as refuting the paradigm, but as the mistake of the researcher, contra Popper's refutability criterion. As anomalous results build up, science reaches a crisis, at which point a new paradigm, which subsumes the old results along with the anomalous results into one framework, is accepted. This is termed revolutionary science.

In SSR, Kuhn also argues that rival paradigms are incommensurable—that is, it is not possible to understand one paradigm through the conceptual framework and terminology of another rival paradigm. For many critics, for example David Stove (Popper and After, 1982), this thesis seemed to entail that theory choice is fundamentally irrational: if rival theories cannot be directly compared, then one cannot make a rational choice as to which one is better. Whether Kuhn's views had such relativistic consequences is the subject of much debate; Kuhn himself denied the accusation of relativism in the third edition of SSR, and sought to clarify his views to avoid further misinterpretation. Freeman Dyson has quoted Kuhn as saying "I am not a Kuhnian!",^[3] referring to the relativism that some philosophers have developed based on his work.

The enormous impact of Kuhn's work can be measured in the changes it brought about in the vocabulary of the philosophy of science: besides "paradigm shift", Kuhn raised the word "paradigm" itself from a term used in certain forms of linguistics to its current broader meaning, coined the term "normal science" to refer to the relatively routine, day-to-day work of scientists working within a paradigm, and was largely responsible for the use of the term "scientific revolutions" in the plural, taking place at widely different periods of time and in different disciplines, as opposed to a single "Scientific Revolution" in the late Renaissance. The frequent use of the phrase "paradigm shift" has made scientists more aware of and in many cases more receptive to paradigm changes, so that Kuhn’s analysis of the evolution of scientific views has by itself influenced that evolution.^{[citation needed]}

Kuhn's work has been extensively used in social science; for instance, in the post-positivist/positivist debate within International Relations. Kuhn is credited as a foundational force behind the post-Mertonian Sociology of Scientific Knowledge.

A defense Kuhn gives against the objection that his account of science from The Structure of Scientific Revolutions results in relativism can be found in an essay by Kuhn called "Objectivity, Value Judgment, and Theory Choice."^[4] In this essay, he reiterates five criteria from the penultimate chapter of SSR that determine (or help determine, more properly) theory choice:

- Accurate - empirically adequate with experimentation and observation
- Consistent - internally consistent, but also externally consistent with other theories
- Broad Scope - a theory's consequences should extend beyond that which it was initially designed to explain
- Simple - the simplest explanation, principally similar to Occam's Razor
- Fruitful - a theory should disclose new phenomena or new relationships among phenomena

He then goes on to show how, although these criteria admittedly determine theory choice, they are imprecise in practice and relative to individual scientists. According to Kuhn, "When scientists must choose between competing theories, two men fully committed to the same list of criteria for choice may nevertheless reach different conclusions."^[4] For this reason, basically, the criteria still are not "objective" in the usual sense of the word because individual scientists reach different conclusions with the same criteria due to valuing one criterion over another or even adding additional criteria for selfish or other subjective reasons. Kuhn then goes on to say, "I am suggesting, of course, that the criteria of choice with which I began function not as rules, which determine choice, but as values, which influence it."^[4] Because Kuhn utilizes the history of science in his account of science, his criteria or values for theory choice are often understood as descriptive normative rules (or more properly, values) of theory choice for the scientific community rather than prescriptive normative rules in the usual sense of the word "criteria," although there are many varied interpretations of Kuhn's account of science.

The Polanyi-Kuhn debate

Scientific historians and scholars have noted similarities between Kuhn's work and the work of Michael Polanyi. Although they used different terminologies, both scientists believed that scientists' subjective experiences made science a relativistic discipline. Polanyi lectured on this topic for decades before Kuhn published "The Structure of Scientific Revolutions."

Supporters of Polanyi charged Kuhn with plagiarism, as it was known that Kuhn attended several of Polanyi's lectures, and that the two men had debated endlessly over the epistemology of science before either had achieved fame. In response to these critics, Kuhn cited Polanyi in the second edition of "The Structure of Scientific Revolutions," ^[5] and the two scientists agreed to set aside their differences in the hopes of enlightening the world to the dynamic nature of science^{[citation needed]}. Despite this intellectual alliance, Polanyi's work was constantly interpreted by others within the framework of Kuhn's paradigm shifts, much to Polanyi's (and Kuhn's) dismay.^[6]

Honors

Kuhn was named a Guggenheim Fellow in 1954, and in 1982 was awarded the George Sarton Medal by the History of Science Society. He was also awarded numerous honorary doctorates.

Bibliography

Bird, Alexander. Thomas Kuhn. Princeton and London: Princeton University Press and Acumen Press, 2000. ISBN 1-902683-10-2
Fuller, Steve.Thomas Kuhn: A Philosophical History for Our Times. Chicago: University of Chicago Press, 2000. ISBN 0-226-26894-2
Sal Restivo, The Myth of the Kuhnian Revolution. Sociological Theory, Vol. 1, (1983), 293-305.
Hoyningen-Huene, Paul (1993): Reconstructing Scientific Revolutions: Thomas S. Kuhn's Philosophy of Science. Chicago: University of Chicago Press.
Kuhn, T.S. The Copernican Revolution: planetary astronomy in the development of Western thought. Cambridge: Harvard University Press, 1957. ISBN 0-674-17100-4
Kuhn, T.S. The Function of Measurement in Modern Physical Science. Isis, 52(1961): 161-193.
Kuhn, T.S. The Structure of Scientific Revolutions. Chicago: University of Chicago Press, 1962. ISBN 0-226-45808-3
Kuhn, T.S. "The Function of Dogma in Scientific Research". Pp. 347-69 in A. C. Crombie (ed.). Scientific Change (Symposium on the History of Science, University of Oxford, 9-15 July 1961). New York and London: Basic Books and Heineman, 1963.
Kuhn, T.S. The Essential Tension: Selected Studies in Scientific Tradition and Change. Chicago and London: University of Chicago Press, 1977. ISBN 0-226-45805-9
Kuhn, T.S. Black-Body Theory and the Quantum Discontinuity, 1894-1912. Chicago: University of Chicago Press, 1987. ISBN 0-226-45800-8
Kuhn, T.S. The Road Since Structure: Philosophical Essays, 1970-1993. Chicago: University of Chicago Press, 2000. ISBN 0-226-45798-2

References

^ Alexander Bird (2004), Thomas Kuhn, Stanford Encyclopedia of Philosophy http://plato.stanford.edu/entries/thomas-kuhn/
^ Horgan, John (May 1991). "Profile: Reluctant Revolutionary". Scientific American: 40.
^ Dyson, Freeman (May 6, 1999). The Sun, the Genome, and the Internet: Tools of Scientific Revolutions. Oxford University Press, Inc.. pp. 144. ISBN 978-0195129427.
^ ^a ^b ^c Kuhn, Thomas (1977). The Essential Tension: Selected Studies in Scientific Tradition and Change. University of Chicago Press. pp. 320–39.
^ See Thomas S. Kuhn, The Structure of Scientific Revolutions. Chicago and London: University of Chicago Press, 1996 (3rd ed.), 44.
^ Moleski, Martin X. "Polanyi vs. Kuhn: Worldviews Apart." The Polanyi Society. Missouri Western State University. Accessed 20 March 2008. http://www.missouriwestern.edu/orgs/polanyi/TAD%20WEB%20ARCHIVE/TAD33-2/TAD33-2-fnl-pg8-24-pdf.pdf

Black-body theory and the quantum discontinuity: 1894-1912 (1978)

External links

Thomas Kuhn (Biography, Outline of Structure of Scientific Revolutions)
"Thomas Kuhn, 73; Devised Science Paradigm" (obituary by Lawrence Van Gelder, New York Times, 19 June 1996)
Thomas S. Kuhn (obituary, The Tech p9 vol 116 no 28, 26 June 1996)
Thomas Kuhn at the Stanford Encyclopedia of Philosophy
Review in the New York Review of Books
Color Photo
History of Twentieth-Century Philosophy of Science BOOK VI: Kuhn on Revolution and Feyerabend on Anarchy - with free downloads for public use.
article on his Road Since Structure: Philosophical Essays
John Horgan's Interview http://www.stevens.edu/csw/cgi-bin/shapers/kuhn/

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