Dynamics of shear-transformation zones in amorphous plasticity: large-scale deformation in a two-dimensional geometry

TL;DR

This study numerically investigates shear-transformation-zone (STZ) theory in 2D, examining how different geometries, strain rates, and initial conditions influence deformation patterns like necking and shear band formation.

Contribution

It extends the 2D STZ model to simulate uniaxial tension, analyzing effects of material parameters and initial conditions on deformation behaviors.

Findings

Higher epsilon_0 increases plastic flow and sharpens necks.

Lower strain rates promote narrow shear band formation.

Pre-annealed conditions lead to more strain localization and brittleness.

Abstract

A two-dimensional version of the shear-transformation-zone (STZ) theory by Falk and Langer is explored numerically. Two different geometries are used to simulate uniaxial tension experiments where materials are subjected to constant strain rates. In the first setup, a rectangular specimen is given an imperceptible indentation, allowing it to neck at the center. The dynamics are explored systematically by varying both the straining capability of the STZs (epsilon_0) and the external strain rate. Higher values of epsilon_0 increase the plastic flow and result in sharper necks. Decreased values of the external strain rate result in the formation of narrow shear bands, consistent with the absence of thermal relaxation mechanisms in the model. In the second configuration, the equivalent of pre-annealed materials are explored. Here, the sample is initially square and the edges are made rough in order to encourage the formation of shear bands. With respect to epsilon_0 and the external strain rate, the results show trends similar to those in the necking simulations. The pre-annealing was modeled by using a low initial density of STZs. This had most effect when epsilon_0 was large, contributing to the localization of the strain and making the material appear more brittle.