Controlling assembly and oscillations of elastic membranes with an active fluid

arXiv - PHYS - Soft Condensed Matter Pub Date : 2024-08-26 DOI:arxiv-2408.14699

John Berezney, Sattvic Ray, Itamar Kolvin, Mark Bowick, Seth Fraden, Zvonimir Dogic

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Abstract

We use the chaotic flows generated by a microtubule-based active fluid to assemble self-binding actin filaments into a thin elastic sheets. Starting from a uniformly dispersed state, active flows drive the motion of actin filaments, inducing their bundling and formation of bundle-bundle connections that ultimately generate an elastic network. The emerging network separates from the active fluid to form a thin elastic sheets suspended at the sample midplane. At intermediate times, the active fluid drives large in-plane and out-of-plane deformations of the elastic sheet which are driven by low-energy bending modes. Self-organized sheets eventually exhibit centimeter-sized global spontaneous oscillations and traveling waves, despite being isotropically driven on micron lengths by the active fluid. The active assembly generates diverse network structures which are not easily realizable with conventional paradigms of equilibrium self-assembly and materials processing. Self-organized mechanical sheets pose a challenge for understanding of how a hierarchy of structure, mechanics, and dynamics emerges from a largely structureless initial suspension of active and passive microscopic components.

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用活性流体控制弹性膜的组装和振荡

我们利用基于微管的活性流体产生的混沌流，将自我结合的肌动蛋白丝组装成弹性薄片。从均匀分散的状态开始，活性流体驱动肌动蛋白丝运动，诱导其捆绑并形成束-束连接，最终生成弹性网络。新出现的网络与活性流体分离，形成悬浮在样品中平面的弹性薄片。自组织薄片最终表现出厘米大小的全局自发振荡和行波，尽管活性流体在微米长度上等向驱动。这种主动组装产生了多样化的网络结构，而传统的平衡自组装和材料加工模式很难实现这些结构。自组织机械片对理解结构、力学和动力学的层次结构如何从主动和被动微观成分的基本无结构初始悬浮液中产生提出了挑战。

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 - Soft Condensed Matter

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