Stress correlations in frictional granular media

arXiv: Soft Condensed Matter Pub Date : 2020-08-29 DOI:10.1103/PHYSREVB.103.054110

A. Lemaître, C. Mondal, I. Procaccia, Saikat Roy

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引用次数: 8

Abstract

This paper investigates whether in frictional granular packings, like in Hamiltonian amorphous elastic solids, the stress autocorrelation matrix presents long range anisotropic contributions just as elastic Green's functions. We find that in a standard model of frictional granular packing this is not the case. We prove quite generally that mechanical balance and material isotropy constrain the stress auto-correlation matrix to be fully determined by two spatially isotropic functions: the pressure and torque auto-correlations. The pressure and torque fluctuations being respectively normal and hyperuniform force the stress autocorrelation to decay as the elastic Green's function. Since we find the torque fluctuations to be hyper-uniform, the culprit is the pressure whose fluctuations decay slower than normally as a function of the system's size. Investigating the reason for these abnormal pressure fluctuations we discover that anomalous correlations build up already during the compression of the dilute system before jamming. Once jammed these correlations remain frozen. Whether this is true for frictional matter in general or is it the consequence of the model properties is a question that must await experimental scrutiny and possible alternative models.

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摩擦颗粒介质中的应力相关性

本文研究了在摩擦颗粒填料中，应力自相关矩阵是否与弹性格林函数一样具有长程各向异性贡献。我们发现，在摩擦颗粒填料的标准模型中，情况并非如此。我们相当普遍地证明，机械平衡和材料各向同性约束应力自相关矩阵完全由两个空间各向同性函数:压力和扭矩自相关。压力和转矩波动分别为正态和超均匀，使应力自相关以弹性格林函数衰减。由于我们发现转矩波动是超均匀的，其罪魁祸首是压力，其波动作为系统大小的函数比通常情况下衰减得慢。研究这些异常压力波动的原因，我们发现在干扰之前，在稀释系统的压缩过程中已经建立了异常相关性。一旦堵塞，这些相关性就会冻结。对于一般的摩擦物质来说，这是正确的，还是模型性质的结果，这是一个必须等待实验审查和可能的替代模型的问题。

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: Soft Condensed Matter

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