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OverviewFrom the beginning, the implications of quantum theory for our most general understanding of the world have been a matter of intense debate. Einstein argues that the theory had to be regarded as fundamentally incomplete. Its inability, for example, to predict the exact time of decay of a single radioactive atom had to be due to a failure of the theory and not due to a permanent inability on our part or a fundamental indeterminism in nature itself. /// In 1964, John Bell derived a theorem which showed that any deterministic theory which preserved ""locality"" (i.e., which rejected action at a distance) would have certain consequences for measurements performed at a distance from one another. An experimental check seems to show that these consequences are not, in fact, realized. The correlation between the sets of events is much stronger than any ""local"" deterministic theory could allow. What is more, this stronger correlation is precisely that which is predicted by quantum theory. The astonishing result is that local deterministic theories of the classical sort seem to be permanently excluded. Not only can the individual decay not be predicted, but no future theory can ever predict it. /// The contributors in this volume wrestle with this conclusion. Some welcome it; others leave open a return to at lease some kind of deterministic world, one which must however allow something like action-at-a distance. How much lit it? And how can one avoid violating relativity theory, which excludes action-at-a-distance? How can a clash between the two fundamental theories of modern physics, relativity and quantum theory, be avoided? What are the consequences for the traditional philosophic issue of causality explanation and objectivity? One thing is certain; we can never return to the comfortable Newtonian world where everything that happened was, in principle, predictable and where what happened at one measurement site could not affect another set of measurements being performed light-years away, at a distance that a light-signal could not bridge. /// Contributors: James T. Cushing, Abner Shimony, N. David Mermin, Jon P. Jarrett, Linda Wessels, Bas C. van Fraassen, Jeremy Butterfield, Michael L. G. Redhead, Henry P. Stapp, Arthur Fine, R. I. G. Hughes, Paul Teller, Don Howard, Henry J. Folse, and Ernan McMullin. Full Product DetailsAuthor: James T. Cushing , Ernan McMullinPublisher: University of Notre Dame Press Imprint: University of Notre Dame Press Volume: v. 2 Dimensions: Width: 15.20cm , Height: 1.80cm , Length: 22.90cm Weight: 0.445kg ISBN: 9780268015794ISBN 10: 0268015791 Pages: 330 Publication Date: 31 July 1992 Audience: College/higher education , General/trade , Postgraduate, Research & Scholarly , General Format: Paperback Publisher's Status: Active Availability: Awaiting stock The supplier is currently out of stock of this item. It will be ordered for you and placed on backorder. Once it does come back in stock, we will ship it out for you. Table of ContentsReviewsProminent philosopher-scientists, from Abner Shimony to Paul Teller, contribute articles . . . detailing presumptions and ambiguities of quantum measurement, written especially for the nonspecialist. Some highlights include Mermin's powerful (and amusing) 'device' to highlight the 'paradox' of quantum correlations, Linda Wessels' thorough catalog of specific implicit 'axioms' of the discussion, and Cushing's prospective overview. Other gems, including some simplified models of Bell's arguments, and a range of ontological frameworks--from realism to 'holism'--make this an urgently recommended work. -- Choice Author InformationJames T. Cushing (1937 - 2002) was a US-American theoretical physicist and philosopher of science. He was professor of physics as well as professor of philosophy at the University of Notre Dame. Ernan McMullin (1924–2011) was John Cardinal O'Hara Professor Emeritus of Philosophy at the University of Notre Dame. Tab Content 6Author Website:Countries AvailableAll regions |