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Quantum thermodynamics of nonequilibrium. Onsager reciprocity and dispersion-dissipation relations
Foundations of Physics 17 (4):365-381 (1987)
Abstract
A generalized Onsager reciprocity theorem emerges as an exact consequence of the structure of the nonlinear equation of motion of quantum thermodynamics and is valid for all the dissipative nonequilibrium states, close and far from stable thermodynamic equilibrium, of an isolated system composed of a single constituent of matter with a finite-dimensional Hilbert space. In addition, a dispersion-dissipation theorem results in a precise relation between the generalized dissipative conductivity that describes the mutual interrelation between dissipative rates of a pair of observables and the codispersions of the same observables and the generators of the motion. These results are presented together with a review of quantum thermodynamic postulates and general resultsAuthor's Profile
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References found in this work
The empirical determination of quantum states.William Band & James L. Park - 1970 - Foundations of Physics 1 (2):133-144.
A unified quantum theory of mechanics and thermodynamics. Part I. Postulates.George N. Hatsopoulos & Elias P. Gyftopoulos - 1976 - Foundations of Physics 6 (1):15-31.
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