Ordering, spontaneous flows and aging in active fluids depositing tracks

arXiv - PHYS - Biological Physics Pub Date : 2024-09-08 DOI:arxiv-2409.05195

Samuel Bell, Joseph Ackermann, Ananyo Maitra, Raphael Voituriez

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Abstract

Growing experimental evidence shows that cell monolayers can induce long-lived perturbations to their environment, akin to footprints, which in turn influence the global dynamics of the system. Inspired by these observations, we propose a comprehensive theoretical framework to describe systems where an active field dynamically interacts with a non-advected footprint field, deposited by the active field. We derive the corresponding general hydrodynamics for both polar and nematic fields. Our findings reveal that the dynamic coupling to a footprint field induces remarkable effects absent in classical active hydrodynamics, such as symmetry-dependent modifications to the isotropic-ordered transition, which may manifest as either second-order or first-order, alterations in spontaneous flow transitions, potentially resulting in oscillating flows and rotating fields, and initial condition-dependent aging dynamics characterized by long-lived transient states. Our results suggest that footprint deposition could be a key mechanism determining the dynamical phases of cellular systems, or more generally active systems inducing long-lived perturbations to their environment.

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活性流体沉积轨道的有序、自发流动和老化

越来越多的实验证据表明，细胞单层可以对其环境产生类似脚印的长效扰动，进而影响系统的整体动力学。受这些观察结果的启发，我们提出了一个全面的理论框架，以描述活性场与活性场沉积的非对流脚印场动态相互作用的系统。我们为极性场和向列场推导出了相应的一般流体力学。我们的研究结果表明，与足迹场的动态耦合诱发了经典有源流体力学中不存在的显著效应，例如各向同性有序转变的对称性依赖性修改（可能表现为二阶或一阶）、自发流动转变的改变（可能导致振荡流和旋转场）以及以长寿命瞬态为特征的初始条件依赖性老化动力学。我们的研究结果表明，足迹沉积可能是决定细胞系统动力学阶段的一个关键机制，或者更广泛地说，是决定对其环境产生长效扰动的活性系统的一个关键机制。

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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arXiv - PHYS - Biological Physics

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