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Main Authors: Chiu, Yu-Jen, Weiner, Eric M., Omar, Ahmad K.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.23906
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author Chiu, Yu-Jen
Weiner, Eric M.
Omar, Ahmad K.
author_facet Chiu, Yu-Jen
Weiner, Eric M.
Omar, Ahmad K.
contents The linear laws of transport phenomena are central in our description of irreversible processes in systems across the physical sciences. Linear irreversible thermodynamics allows for the identification of the underlying forces driving transport and the structure of the relevant transport coefficients for systems that are locally in equilibrium. Increasingly, linear relations are found to describe transport in systems in which a local equilibrium hypothesis is unlikely to hold. Here, we derive a mechanical theory of multicomponent transport without appealing to equilibrium notions. Our theory for the Onsager transport tensor highlights the general breakdown of the familiar Onsager reciprocal relations and Einstein relations when a local equilibrium is absent. The procedure outlined is applied to a variety of systems, including passive systems, mixtures with nonreciprocal interactions, electrolytes under an electric field, and active systems, and can be straightforwardly used to understand other transport processes. The framework further provides a basis to extend numerical approaches for computing the transport coefficients of nonequilibrium systems, as is demonstrated for a system with nonreciprocal interactions.
format Preprint
id arxiv_https___arxiv_org_abs_2505_23906
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Multicomponent Linear Transport in the Absence of Local Equilibrium
Chiu, Yu-Jen
Weiner, Eric M.
Omar, Ahmad K.
Statistical Mechanics
The linear laws of transport phenomena are central in our description of irreversible processes in systems across the physical sciences. Linear irreversible thermodynamics allows for the identification of the underlying forces driving transport and the structure of the relevant transport coefficients for systems that are locally in equilibrium. Increasingly, linear relations are found to describe transport in systems in which a local equilibrium hypothesis is unlikely to hold. Here, we derive a mechanical theory of multicomponent transport without appealing to equilibrium notions. Our theory for the Onsager transport tensor highlights the general breakdown of the familiar Onsager reciprocal relations and Einstein relations when a local equilibrium is absent. The procedure outlined is applied to a variety of systems, including passive systems, mixtures with nonreciprocal interactions, electrolytes under an electric field, and active systems, and can be straightforwardly used to understand other transport processes. The framework further provides a basis to extend numerical approaches for computing the transport coefficients of nonequilibrium systems, as is demonstrated for a system with nonreciprocal interactions.
title Multicomponent Linear Transport in the Absence of Local Equilibrium
topic Statistical Mechanics
url https://arxiv.org/abs/2505.23906