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Main Authors: De Bievre, Stephan, Merkli, Marco, Parris, Paul E.
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2312.14290
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author De Bievre, Stephan
Merkli, Marco
Parris, Paul E.
author_facet De Bievre, Stephan
Merkli, Marco
Parris, Paul E.
contents Rigorous derivations of the approach of individual elements of large isolated systems to a state of thermal equilibrium, starting from arbitrary initial states, are exceedingly rare. This is particularly true for quantum mechanical systems. We demonstrate here how, through a mechanism of repeated scattering, an approach to equilibrium of this type actually occurs in a specific quantum system, one that can be viewed as a natural quantum analog of several previously studied classical models. In particular, we consider an optical mode passing through a reservoir composed of a large number of sequentially-encountered modes of the same frequency, each of which it interacts with through a beam splitter. We then analyze the dependence of the asymptotic state of this mode on the assumed stationary common initial state $σ$ of the reservoir modes and on the transmittance $τ=\cosλ$ of the beam splitters. These results allow us to establish that at small $λ$ such a mode will, starting from an arbitrary initial system state $ρ$, approach a state of thermal equilibrium even when the reservoir modes are not themselves initially thermalized. We show in addition that, when the initial states are pure, the asymptotic state of the optical mode is maximally entangled with the reservoir and exhibits less nonclassicality than the state of the reservoir modes.
format Preprint
id arxiv_https___arxiv_org_abs_2312_14290
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Rigorous results on approach to thermal equilibrium, entanglement, and nonclassicality of an optical quantum field mode scattering from the elements of a non-equilibrium quantum reservoir
De Bievre, Stephan
Merkli, Marco
Parris, Paul E.
Quantum Physics
Mathematical Physics
Rigorous derivations of the approach of individual elements of large isolated systems to a state of thermal equilibrium, starting from arbitrary initial states, are exceedingly rare. This is particularly true for quantum mechanical systems. We demonstrate here how, through a mechanism of repeated scattering, an approach to equilibrium of this type actually occurs in a specific quantum system, one that can be viewed as a natural quantum analog of several previously studied classical models. In particular, we consider an optical mode passing through a reservoir composed of a large number of sequentially-encountered modes of the same frequency, each of which it interacts with through a beam splitter. We then analyze the dependence of the asymptotic state of this mode on the assumed stationary common initial state $σ$ of the reservoir modes and on the transmittance $τ=\cosλ$ of the beam splitters. These results allow us to establish that at small $λ$ such a mode will, starting from an arbitrary initial system state $ρ$, approach a state of thermal equilibrium even when the reservoir modes are not themselves initially thermalized. We show in addition that, when the initial states are pure, the asymptotic state of the optical mode is maximally entangled with the reservoir and exhibits less nonclassicality than the state of the reservoir modes.
title Rigorous results on approach to thermal equilibrium, entanglement, and nonclassicality of an optical quantum field mode scattering from the elements of a non-equilibrium quantum reservoir
topic Quantum Physics
Mathematical Physics
url https://arxiv.org/abs/2312.14290