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Main Authors: Meyberg, E., Robinson, J. F., Speck, T.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.12481
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author Meyberg, E.
Robinson, J. F.
Speck, T.
author_facet Meyberg, E.
Robinson, J. F.
Speck, T.
contents Virtually every biological function emerges through the organization of molecules in time and space. Consequently, a major challenge in statistical physics is to uncover the universal principles governing macromolecular self-organization within the crowded, non-equilibrium environment of the cell. Here, we investigate a class of models where molecules maintain a conserved total concentration but can switch "identities", thereby modulating their intermolecular interactions. By enforcing thermodynamic consistency via the local detailed balance condition, we derive the steady-state criteria determining coexisting concentrations in a binary mixture. For non-constant transition rates and using a sharp-interface approximation, we obtain jump conditions that generalize Gibbs' coexistence criteria of equal pressure and chemical potential. We demonstrate that these jumps balance the chemical potential differences of individual species against their currents, which are confined to the interfacial region.
format Preprint
id arxiv_https___arxiv_org_abs_2603_12481
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Impact of currents on non-equilibrium coexistence in chemically driven mixtures
Meyberg, E.
Robinson, J. F.
Speck, T.
Statistical Mechanics
Virtually every biological function emerges through the organization of molecules in time and space. Consequently, a major challenge in statistical physics is to uncover the universal principles governing macromolecular self-organization within the crowded, non-equilibrium environment of the cell. Here, we investigate a class of models where molecules maintain a conserved total concentration but can switch "identities", thereby modulating their intermolecular interactions. By enforcing thermodynamic consistency via the local detailed balance condition, we derive the steady-state criteria determining coexisting concentrations in a binary mixture. For non-constant transition rates and using a sharp-interface approximation, we obtain jump conditions that generalize Gibbs' coexistence criteria of equal pressure and chemical potential. We demonstrate that these jumps balance the chemical potential differences of individual species against their currents, which are confined to the interfacial region.
title Impact of currents on non-equilibrium coexistence in chemically driven mixtures
topic Statistical Mechanics
url https://arxiv.org/abs/2603.12481