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Auteur principal: Barkan, Casey O.
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2404.05123
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author Barkan, Casey O.
author_facet Barkan, Casey O.
contents This work explores the manner in which classical phase space distribution functions converge to the microcanonical distribution. We first prove a theorem about the lack of convergence, then define a generalization of the coarse-graining procedure that leads to convergence. We prove that the time evolution of phase space distributions is an isometry for a broad class of statistical distance metrics, implying that ensembles do not get any closer to (or farther from) equilibrium, according to these metrics. This extends the known result that strong convergence of phase space distributions to the microcanonical distribution does not occur. However, it has long been known that weak convergence can occur, such that coarse-grained distributions--defined by partitioning phase space into a finite number of cells--converge pointwise to the microcanonical distribution. We define a generalization of coarse-graining that removes the need for partitioning phase space into cells. We prove that our generalized coarse-grained distribution converges pointwise to the microcanonical distribution if the dynamics are strong mixing. As an example, we study an ensemble of triangular billiard systems.
format Preprint
id arxiv_https___arxiv_org_abs_2404_05123
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle On the convergence of phase space distributions to microcanonical equilibrium: dynamical isometry and generalized coarse-graining
Barkan, Casey O.
Statistical Mechanics
This work explores the manner in which classical phase space distribution functions converge to the microcanonical distribution. We first prove a theorem about the lack of convergence, then define a generalization of the coarse-graining procedure that leads to convergence. We prove that the time evolution of phase space distributions is an isometry for a broad class of statistical distance metrics, implying that ensembles do not get any closer to (or farther from) equilibrium, according to these metrics. This extends the known result that strong convergence of phase space distributions to the microcanonical distribution does not occur. However, it has long been known that weak convergence can occur, such that coarse-grained distributions--defined by partitioning phase space into a finite number of cells--converge pointwise to the microcanonical distribution. We define a generalization of coarse-graining that removes the need for partitioning phase space into cells. We prove that our generalized coarse-grained distribution converges pointwise to the microcanonical distribution if the dynamics are strong mixing. As an example, we study an ensemble of triangular billiard systems.
title On the convergence of phase space distributions to microcanonical equilibrium: dynamical isometry and generalized coarse-graining
topic Statistical Mechanics
url https://arxiv.org/abs/2404.05123