Contact force measurements and local anisotropy in ellipses and disks

TL;DR

This study provides detailed measurements of contact forces in ellipses and disks, revealing how local anisotropy influences force distribution widths and contact growth under compression, advancing understanding of granular material mechanics.

Contribution

It introduces precise force measurements in anisotropic particles, demonstrating the influence of local anisotropy on force distributions and contact growth in granular materials.

Findings

Local stress ratio controls force distribution width.

Anisotropic particle shape affects contact growth under compression.

Non-affine motions homogenize force distributions.

Abstract

Experimental measurements of contact forces are limited to spheres and disks in three and two dimensions, making the evaluation of the shape effect and universality of force distributions and the comparison between experiments and theories extremely difficult. Here we present precise measurements of vector contact forces in photoelastic ellipses and disks subject to isotropic compression and pure shear. We find the local, instead of the global, stress ratio, control the width of the force distributions for forces larger than the mean, regardless of the particle shape and preparation protocols. By taking advantage of the anisotropic particle shape, we can determine the anisotropic growth of contacts in ellipses subject to isotropic compression, revealing the role of non-affine particle motions in homogenizing force distributions. Our results uncover the role of local anisotropy in the statistical framework of granular materials and open a new regime of exploring the role of particle shape on the mechanical and dynamical properties of granular materials in depth.