Fluctuations in crystalline plasticity

TL;DR

This paper reviews recent findings on the critical dynamics and fluctuations in crystalline plasticity, emphasizing size effects, disorder influence, and methods to control plastic intermittency in micro- and nano-scale systems.

Contribution

It provides a comprehensive review of the physical origins, scaling, and emergent behaviors of plastic fluctuations, highlighting the role of size, disorder, and alloying in controlling plasticity.

Findings

Dislocation avalanches exhibit long-tailed size and energy distributions.

Plastic response becomes intermittent and size-dependent at micro- and nano-scales.

Controlling quenched disorder can tame plastic flow fluctuations.

Abstract

Recently acoustic signature of dislocation avalanches in HCP materials was found to be long tailed in size and energy, suggesting critical dynamics. Even more recently, the intermittent plastic response was found to be generic for micro- and nano-sized systems independently of their crystallographic symmetry. These rather remarkable discoveries are reviewed in this paper in the perspective of the recent studies performed in our group. We discuss the physical origin and the scaling properties of plastic fluctuations and address the nature of their dependence on crystalline symmetry, system size, and disorder content. A particular emphasis is placed on the associated emergent behaviors, including the formation of dislocation structures, and on our ability to temper plastic fluctuations by alloying. We also discuss the "smaller is wilder" size effect that culminates in a paradoxical crack-free brittle behavior of very small, initially dislocation free crystals. We show that the implied transition between different rheological behaviors is regulated by the ratio of length scales $R=L/l$, where $L$ is the system size and $l$ is the internal length. We link this new size effect with other related phenomena like size dependence of strength ("smaller is stronger") and the size induced switch between different hardening mechanisms. One of the technological challenges in nanoscience is to tame the intermittency of plastic flow. We show that this task can be accomplished by generating tailored quenched disorder which allows one to control micro- and nano-scale forming and opens new perspectives in micro-metallurgy and structural engineering of ultra-small load-carrying elements. These results could not be achieved by conventional methods that do not explicitly consider the stochastic nature of collective dislocation dynamics.