Investigating the relation between elastic and relaxation properties of dry, frictional granular media during shear deformation

TL;DR

This study uses discrete element simulations to explore how elastic and relaxation properties of dry, frictional granular media evolve during shear deformation, revealing complex rheological behavior influenced by elastic damage and microstructural rearrangements.

Contribution

It provides new insights into the interplay between elastic stiffness, damage, and relaxation dynamics in granular media during shear, extending beyond traditional rheological models.

Findings

Elastic stiffness persists throughout shear deformation.

Stress relaxation follows a compressed exponential form.

Elastic damage influences residual stresses and rheological transition.

Abstract

Using discrete element simulations based on molecular dynamics, we investigate the mechanical behavior of sheared, dry, frictional granular media in the "dense" and "critical" regimes. We find that this behavior is partitioned between transient stages and a final stationary stage. While the later is macroscopically consistent with the predictions of the viscous, $\mu(I)$ rheology, both the macroscopic behavior during the transient stages and the overall microscopic behavior suggest a more complex picture. Indeed, the simulated granular medium exhibits a finite elastic stiffness throughout its entire shear deformation history, although topological rearrangements of the grains at the microscale translate into a partial degradation of this stiffness, which can be interpreted as a form of elastic damage. The relaxation of stresses follows a compressed exponential, also highlighting the role of elastic interactions in the medium, with residual stresses that depend on the level of elastic damage. The established relations between elastic and relaxation properties point to a complex rheology, characterized by a damage-dependent transition between a visco-elasto-plastic and a viscous behavior.