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Chaos in a Model of an Open Quantum System

Published online by Cambridge University Press:  01 April 2022

Frederick M. Kronz*
Affiliation:
The University of Texas at Austin
*
Send requests for reprints to the author, Department of Philosophy, The University of Texas at Austin, Austin, TX 78712; email: [email protected].

Abstract

In a previous essay I argued that quantum chaos cannot be exhibited in models of quantum systems within von Neumann's mathematical framework for quantum mechanics, and that it can be exhibited in models within Dirac's formal framework. In this essay, the negative thesis concerning von Neumann's framework is elaborated further by extending it to the case of Hamiltonian operators having a continuous spectrum. The positive thesis concerning Dirac's formal framework is also elaborated further by constructing a chaotic model of an open quantum system in which an entropy measure is shown to approach its maximum value as time goes to infinity. Having such an entropy measure is a characteristic that is closely connected to chaotic behavior in phase space models of classical systems.

Type
Philosophy of Physics and Chemistry
Copyright
Copyright © 2000 by the Philosophy of Science Association

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Footnotes

This essay was completed with support from the National Science Foundation, grant number SBR-9602122. I would like to thank Charles Radin for his expert assistance with some of the technical issues involved in the second section of this essay having to do with the spectral representation of bounded and unbounded operators in an infinite-dimensional separable Hilbert space.

References

Akhiezer, Naum I. and Glazman, Izrail M. (1993), Theory of Linear Operators in Hilbert Space. New York: Dover Publications. [Originally published in New York by F. Ungar Pub. Co., 1961, 1963.]Google Scholar
Daróczy, Zoltán (1970), “Generalized Information Functions”, Information and Control 16: 3651.CrossRefGoogle Scholar
Dirac, Paul A. M. (1958), The Principles of Quantum Mechanics. Oxford: Oxford University Press. [1st ed., 1930.]CrossRefGoogle Scholar
Gel'fand, Izrail M. and Shilov, Georgii E. (1967), Generalized Functions III: Theory of Differential Equations. New York: Academic Press. [First published in Russian in 1958.]Google Scholar
Gel'fand, Izrail M. and Vilenkin, Naum Y. (1964), Generalized Functions IV: Applications of Harmonic Analysis. New York: Academic Press. [First published in Russian in 1961.]Google Scholar
Jordan, Thomas F. (1969), Linear Operators for Quantum Mechanics. New York: Wiley.CrossRefGoogle Scholar
Kronz, Frederick M. (1998), “Nonseparability and Quantum Chaos,” Philosophy of Science 65: 5075.CrossRefGoogle Scholar
Reed, Michael and Simon, Barry (1980), Methods of Modern Mathematical Physics, Volume I: Functional Analysis. New York: Academic Press.Google Scholar
Von Neumann, John (1955), Mathematical Foundations of Quantum Mechanics. Princeton: Princeton University Press. [First published in German in 1932.]Google Scholar