On the critical nature of plastic flow: one and two dimensional models

TL;DR

This paper introduces minimal one- and two-dimensional models to explain the scale-free fluctuations and complex behavior observed in plastic flow, linking microscopic stability to macroscopic phenomena.

Contribution

It presents a novel mesoscopic automaton model that captures critical exponents and fractal patterns in plasticity, advancing understanding beyond conventional smooth models.

Findings

One-dimensional model reproduces main macroscopic plasticity features.

Two-dimensional model captures power law avalanche statistics.

Model shows finite size scaling and realistic shape functions.

Abstract

Steady state plastic flows have been compared to developed turbulence because the two phenomena share the inherent complexity of particle trajectories, the scale free spatial patterns and the power law statistics of fluctuations. The origin of the apparently chaotic and at the same time highly correlated microscopic response in plasticity remains hidden behind conventional engineering models which are based on smooth fitting functions. To regain access to fluctuations, we study in this paper a minimal mesoscopic model whose goal is to elucidate the origin of scale free behavior in plasticity. We limit our description to fcc type crystals and leave out both temperature and rate effects. We provide simple illustrations of the fact that complexity in rate independent athermal plastic flows is due to marginal stability of the underlying elastic system. Our conclusions are based on a reduction of an over-damped visco-elasticity problem for a system with a rugged elastic energy landscape to an integer valued automaton. We start with an overdamped one dimensional model and show that it reproduces the main macroscopic phenomenology of rate independent plastic behavior but falls short of generating self similar structure of fluctuations. We then provide evidence that a two dimensional model is already adequate for describing power law statistics of avalanches and fractal character of dislocation patterning. In addition to capturing experimentally measured critical exponents, the proposed minimal model shows finite size scaling collapse and generates realistic shape functions in the scaling laws.