Quantum mechanical evolution towards thermal equilibrium

Noah Linden; Sandu Popescu; Anthony J. Short; Andreas Winter

doi:10.1103/PhysRevE.79.061103

Quantum mechanical evolution towards thermal equilibrium

Noah Linden^*, Sandu Popescu, Anthony J. Short, Andreas Winter

^*Autor corresponent d’aquest treball

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Resum

The circumstances under which a system reaches thermal equilibrium, and how to derive this from basic dynamical laws, has been a major question from the very beginning of thermodynamics and statistical mechanics. Despite considerable progress, it remains an open problem. Motivated by this issue, we address the more general question of equilibration. We prove, with virtually full generality, that reaching equilibrium is a universal property of quantum systems: almost any subsystem in interaction with a large enough bath will reach an equilibrium state and remain close to it for almost all times. We also prove several general results about other aspects of thermalization besides equilibration, for example, that the equilibrium state does not depend on the detailed microstate of the bath.

Idioma original	Anglès
Número d’article	061103
Nombre de pàgines	12
Revista	Physical Review E - Statistical, Nonlinear, and Soft Matter Physics
Volum	79
Número	6
DOIs	https://doi.org/10.1103/PhysRevE.79.061103
Estat de la publicació	Publicada - 4 de juny 2009

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title = "Quantum mechanical evolution towards thermal equilibrium",

abstract = "The circumstances under which a system reaches thermal equilibrium, and how to derive this from basic dynamical laws, has been a major question from the very beginning of thermodynamics and statistical mechanics. Despite considerable progress, it remains an open problem. Motivated by this issue, we address the more general question of equilibration. We prove, with virtually full generality, that reaching equilibrium is a universal property of quantum systems: almost any subsystem in interaction with a large enough bath will reach an equilibrium state and remain close to it for almost all times. We also prove several general results about other aspects of thermalization besides equilibration, for example, that the equilibrium state does not depend on the detailed microstate of the bath.",

author = "Noah Linden and Sandu Popescu and Short, {Anthony J.} and Andreas Winter",

year = "2009",

month = jun,

day = "4",

doi = "10.1103/PhysRevE.79.061103",

language = "English",

volume = "79",

journal = "Physical Review E - Statistical, Nonlinear, and Soft Matter Physics",

issn = "1539-3755",

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T1 - Quantum mechanical evolution towards thermal equilibrium

AU - Linden, Noah

AU - Popescu, Sandu

AU - Short, Anthony J.

AU - Winter, Andreas

PY - 2009/6/4

Y1 - 2009/6/4

N2 - The circumstances under which a system reaches thermal equilibrium, and how to derive this from basic dynamical laws, has been a major question from the very beginning of thermodynamics and statistical mechanics. Despite considerable progress, it remains an open problem. Motivated by this issue, we address the more general question of equilibration. We prove, with virtually full generality, that reaching equilibrium is a universal property of quantum systems: almost any subsystem in interaction with a large enough bath will reach an equilibrium state and remain close to it for almost all times. We also prove several general results about other aspects of thermalization besides equilibration, for example, that the equilibrium state does not depend on the detailed microstate of the bath.

AB - The circumstances under which a system reaches thermal equilibrium, and how to derive this from basic dynamical laws, has been a major question from the very beginning of thermodynamics and statistical mechanics. Despite considerable progress, it remains an open problem. Motivated by this issue, we address the more general question of equilibration. We prove, with virtually full generality, that reaching equilibrium is a universal property of quantum systems: almost any subsystem in interaction with a large enough bath will reach an equilibrium state and remain close to it for almost all times. We also prove several general results about other aspects of thermalization besides equilibration, for example, that the equilibrium state does not depend on the detailed microstate of the bath.

UR - http://www.scopus.com/inward/record.url?scp=67650902389&partnerID=8YFLogxK

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DO - 10.1103/PhysRevE.79.061103

M3 - Article

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SN - 1539-3755

VL - 79

JO - Physical Review E - Statistical, Nonlinear, and Soft Matter Physics

JF - Physical Review E - Statistical, Nonlinear, and Soft Matter Physics

IS - 6

M1 - 061103

ER -

Quantum mechanical evolution towards thermal equilibrium

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