非平衡多组分共存理论

arXiv - PHYS - Statistical Mechanics Pub Date : 2024-09-11 DOI:arxiv-2409.07620

Yu-Jen Chiu, Daniel Evans, Ahmad K. Omar

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引用次数: 0

摘要

多组分相分离是生物和合成系统中经常发生的现象。热力学为确定这些处于平衡状态的系统的相变边界提供了一条捷径。相分离现象在平衡状态之外的复杂系统中非常普遍，这促使我们需要一种真正的非平衡多组分相共存理论。在此，我们提出了一种共存的机械理论，它将共存标准转化为我们熟悉的状态函数相等形式。我们的理论将物种化学势和热力学压力等传统平衡概念推广到了非平衡系统。最重要的是，虽然这些概念可能无法用于所有非平衡系统，但我们通过引入现象学多组分活动模型 B+，从数值上验证了各种系统的共存性。我们的工作为理解多组分共存建立了一个初步框架，希望它能作为高维非平衡相变综合理论的基础。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Theory of Nonequilibrium Multicomponent Coexistence

Multicomponent phase separation is a routine occurrence in both living and synthetic systems. Thermodynamics provides a straightforward path to determine the phase boundaries that characterize these transitions for systems at equilibrium. The prevalence of phase separation in complex systems outside the confines of equilibrium motivates the need for a genuinely nonequilibrium theory of multicomponent phase coexistence. Here, we develop a mechanical theory for coexistence that casts coexistence criteria into the familiar form of equality of state functions. Our theory generalizes traditional equilibrium notions such as the species chemical potential and thermodynamic pressure to systems out of equilibrium. Crucially, while these notions may not be identifiable for all nonequilibrium systems, we numerically verify their existence for a variety of systems by introducing the phenomenological Multicomponent Active Model B+. Our work establishes an initial framework for understanding multicomponent coexistence that we hope can serve as the basis for a comprehensive theory for high-dimensional nonequilibrium phase transitions.

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arXiv - PHYS - Statistical Mechanics

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