各向异性网络中的刚性转换分多个步骤进行

arXiv - PHYS - Statistical Mechanics Pub Date : 2024-09-13 DOI:arxiv-2409.08565

William Y. Wang, Stephen J. Thornton, Bulbul Chakraborty, Anna Barth, Navneet Singh, Japheth Omonira, Jonathan A. Michel, Moumita Das, James P. Sethna, Itai Cohen

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引用次数: 0

摘要

我们研究了三角形晶格中的刚性转变是如何通过优先单向填充晶格上的键来改变各向异性的函数的。我们发现，各向异性弹簧网中刚性的开始至少分为两步，这让人想起二维晶体中的两步熔化转变。我们的模拟特别证明，应力支撑键的渗流发生在沿不同方向的不同临界体积分数上。通过研究弹性张量的每个独立分量，我们确定了普遍指数并开发了普遍缩放函数，以分析作为多临界点的各向同性刚性渗滤。我们希望这些结果对阐明支配生物材料特性的基本机械相变具有重要意义，从细胞的细胞骨架到组织（如肌腱）的细胞外网络，在这些组织中，网络通常是优先排列的。

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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Rigidity transitions in anisotropic networks happen in multiple steps

We study how the rigidity transition in a triangular lattice changes as a function of anisotropy by preferentially filling bonds on the lattice in one direction. We discover that the onset of rigidity in anisotropic spring networks arises in at least two steps, reminiscent of the two-step melting transition in two dimensional crystals. In particular, our simulations demonstrate that the percolation of stress-supporting bonds happens at different critical volume fractions along different directions. By examining each independent component of the elasticity tensor, we determine universal exponents and develop universal scaling functions to analyze isotropic rigidity percolation as a multicritical point. We expect that these results will be important for elucidating the underlying mechanical phase transitions governing the properties of biological materials ranging from the cytoskeletons of cells to the extracellular networks of tissues such as tendon where the networks are often preferentially aligned.

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arXiv - PHYS - Statistical Mechanics

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