A fundamental link between system theory and statistical mechanics

&
Foundations of Physics 17 (9):939-963 (1987)
  Copy   BIBTEX

Abstract

A fundamental link between system theory and statistical mechanics has been found to be established by the Kolmogorov entropy K. By this quantity the temporal evolution of dynamical systems can be classified into regular, chaotic, and stochastic processes. Since K represents a measure for the internal information creation rate of dynamical systems, it provides an approach to irreversibility. The formal relationship to statistical mechanics is derived by means of an operator formalism originally introduced by Prigogine. For a Liouville operator L and an information operator $\tilde M$ acting on a distribution in phase space, it is shown that i[L, $\tilde M$ ]≡KI (I=identity operator). As a first consequence of this equivalence, a relation is obtained between the chaotic correlation time of a system and Prigogine's concept of a “finite duration of presence.” Finally, the existence of chaos in quantum systems is discussed with respect to the existence of a quantum mechanical time operator

Categories

Keywords

Reprint years

DOI

10.1007/bf00734321

Other Versions

No versions found

Links

PhilArchive



    Upload a copy of this work     Papers currently archived: 101,247

External links

Setup an account with your affiliations in order to access resources via your University's proxy server

Through your library

My notes

Similar books and articles

Quantum statistical dynamics: Statistics origin, measurement, and irreversibility. [REVIEW]V. S. Mashkevich - 1985 - Foundations of Physics 15 (1):1-33.
Identities for Entropy Change Associated with the Time-Evolution of an Open System.Hiroki Majima & Akira Suzuki - 2015 - Foundations of Physics 45 (8):914-922.
A quantum mechanical version of the paper by E. Schrödinger “Über die Umkehrung der Naturgesetze”.Otto Bergmann - 1988 - Foundations of Physics 18 (3):373-378.
Macroscopic Time Evolution and MaxEnt Inference for Closed Systems with Hamiltonian Dynamics.Domagoj Kuić, Paško Županović & Davor Juretić - 2012 - Foundations of Physics 42 (2):319-339.
Thermodynamics of chaotic systems : an introduction.Christian Beck & Friedrich Schögl - 1993 - Cambridge University Press.
Derivation of the Quantum Mechanical Momentum Operator in the Position Representation.Ryan Reece - manuscript
Jordan blocks and exponentially decaying higher-order Gamow states.A. Bohm, M. Loewe, P. Patuleanu & C. Püntmann - 1997 - Foundations of Physics 27 (5):613-624.
A probabilistic analysis of the difficulties of unifying quantum mechanics with the theory of relativity.Manfred Neumann - 1978 - Foundations of Physics 8 (9-10):721-733.
Predictive Statistical Mechanics and Macroscopic Time Evolution: Hydrodynamics and Entropy Production.Domagoj Kuić - 2016 - Foundations of Physics 46 (7):891-914.
Hamiltonian Structure of the Schrödinger Classical Dynamical System.Massimo Tessarotto, Michael Mond & Davide Batic - 2016 - Foundations of Physics 46 (9):1127-1167.

Analytics

Added to PP
2013-11-22

Downloads
133 (#166,004)

6 months
7 (#706,906)

Historical graph of downloads
How can I increase my downloads?

Citations of this work

Complementarity in Classical Dynamical Systems.Harald Atmanspacher - 2006 - Foundations of Physics 36 (2):291-306.
Chaos.Robert Bishop - 2015 - Stanford Encyclopedia of Philosophy.
Nonseparability and quantum chaos.Frederick M. Kronz - 1998 - Philosophy of Science 65 (1):50-75.
Determinism is ontic, determinability is epistemic.Harald Atmanspacher - 2002 - In Harald Atmanspacher & Robert Bishop (eds.), Between Chance and Choice: Interdisciplinary Perspectives on Determinism. Thorverton UK: Imprint Academic. pp. 49--74.

View all 7 citations / Add more citations

References found in this work

Transient chaos in quantum and classical mechanics.Boris V. Chirikov - 1986 - Foundations of Physics 16 (1):39-49.

Add more references