Elastoplastic Modelling of Cyclic Shear Deformation of Amorphous Solids

TL;DR

This paper introduces an energy-landscape based elasto-plastic model for amorphous solids under shear, capturing key phenomena like brittle-ductile transition, Bauschinger effect, and cyclic yielding behaviors.

Contribution

It presents a novel mesoscopic model that combines energy landscapes with finite element interactions to simulate cyclic and uniform shear deformation in amorphous solids.

Findings

Reproduces brittle-to-ductile crossover with annealing.

Captures Bauschinger effect in uniform shear.

Models cyclic shear yielding phenomena and failure divergence.

Abstract

We develop an energy-landscape based elasto-plastic model to understand the behaviour of amorphous solids under uniform and cyclic shear. Amorphous solids are modeled as being composed of mesoscopic sub-volumes, each of which may occupy states - termed mesostates -- drawn from a specified distribution. The energies of the mesostates under stress free conditions determine their stability range with respect to applied strain, and their plastic strain, at which they are stress free, forms an important additional property. Under applied global strain, mesostates that reach their stability limits transition to other permissible mesostates. Barring such transitions, which encompass plastic deformations that the solid may undergo, mesostates are treated as exhibiting linear elastic behavior, and the interactions between mesoscopic blocks are treated using the finite element method. The model reproduces known phenomena under uniform and cyclic shear, such as the brittle-to-ductile crossover with annealing and the Bauschinger effect for uniform shear, qualitative features of the yielding diagram under cyclic shear including the change in yielding behaviour with the degree of annealing, across a `threshold level', and dynamic phenomena such as the divergence of failure times on approach to the yield point and the non-monotonic evolution of the local yield rate. In addition to these results, we discuss the dependence of the observed behaviour on model choices, and open questions highlighted by our work.