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Auteurs principaux: Aslyamov, Timur, Esposito, Massimiliano
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2507.07876
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author Aslyamov, Timur
Esposito, Massimiliano
author_facet Aslyamov, Timur
Esposito, Massimiliano
contents Near equilibrium, the symmetric part of the time-integrated steady-state covariance, i.e., the time integral of correlation functions, is governed by the fluctuation-dissipation theorem, while the antisymmetric part vanishes due to Onsager reciprocity. Far from equilibrium, where these principles no longer apply, we develop a unified formalism for both symmetric and antisymmetric components of integrated covariances. We derive exact, computationally tractable expressions for these quantities, valid in arbitrary nonequilibrium steady states of Markov jump processes and Fokker--Planck equation. Both components are expressed in terms of excess observables, a notion central to both statistical physics and reinforcement learning. Furthermore, we establish thermodynamic upper bounds for antisymmetric covariances in terms of (pseudo-)entropy production and cycle affinities. Finally, we show that the speed up of self-averaging induced by nonequilibrium drivings which preserve kinetics (activity) is bounded by the cycle affinities (thermodynamic forces).
format Preprint
id arxiv_https___arxiv_org_abs_2507_07876
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Integrated covariances as excess observables weighted by currents and activities
Aslyamov, Timur
Esposito, Massimiliano
Statistical Mechanics
Near equilibrium, the symmetric part of the time-integrated steady-state covariance, i.e., the time integral of correlation functions, is governed by the fluctuation-dissipation theorem, while the antisymmetric part vanishes due to Onsager reciprocity. Far from equilibrium, where these principles no longer apply, we develop a unified formalism for both symmetric and antisymmetric components of integrated covariances. We derive exact, computationally tractable expressions for these quantities, valid in arbitrary nonequilibrium steady states of Markov jump processes and Fokker--Planck equation. Both components are expressed in terms of excess observables, a notion central to both statistical physics and reinforcement learning. Furthermore, we establish thermodynamic upper bounds for antisymmetric covariances in terms of (pseudo-)entropy production and cycle affinities. Finally, we show that the speed up of self-averaging induced by nonequilibrium drivings which preserve kinetics (activity) is bounded by the cycle affinities (thermodynamic forces).
title Integrated covariances as excess observables weighted by currents and activities
topic Statistical Mechanics
url https://arxiv.org/abs/2507.07876