Models of stress fluctuations in granular media

TL;DR

This paper develops and analyzes scalar and tensorial models for stress propagation in granular media, revealing diffusive and wave-like behaviors, and highlights potential mechanical instabilities due to disorder.

Contribution

It introduces a scalar diffusion-based model and a tensorial wave-based model for stress fluctuations, providing analytical and numerical insights into their behaviors.

Findings

Scalar model exhibits diffusion and stress distribution properties.

Tensorial model shows wave-like stress propagation with disorder-induced diffusion.

Response function can become negative, indicating potential mechanical instability.

Abstract

We investigate in detail two models describing how stresses propagate and fluctuate in granular media. The first one is a scalar model where only the vertical component of the stress tensor is considered. In the continuum limit, this model is equivalent to a diffusion equation (where the r\^ole of time is played by the vertical coordinate) plus a randomly varying convection term. We calculate the response and correlation function of this model, and discuss several properties, in particular related to the stress distribution function. We then turn to the tensorial model, where the basic starting point is a wave equation which, in the absence of disorder, leads to a ray-like propagation of stress. In the presence of disorder, the rays acquire a diffusive width and the angle of propagation is shifted. A striking feature is that the response function becomes negative, which suggests that the contact network is mechanically unstable to very weak perturbations. The stress correlation function reveals characteristic features related to the ray-like propagation, which are absent in the scalar description. Our analytical calculations are confirmed and extended by a numerical analysis of the stochastic wave equation.