Nonlinear plastic modes in disordered solids
Abstract
We propose a framework within which a robust mechanical definition of precursors to plastic instabilities, often termed `soft-spots', naturally emerges. They are shown to be collective displacements (modes) that correspond to local minima of the `barrier function' . The latter is derived from the cubic approximation of the variation of the potential energy upon displacing particles a distance along . We show that modes corresponding to low-lying minima of lead to transitions over energy barriers in the glass, and are therefore associated with highly asymmetric variations with . We further demonstrate how a heuristic search for local minima of can a-priori detect the locus and geometry of imminent plastic instabilities with remarkable accuracy, at strains as large as away from the instability strain , where the non-affine displacements under shear are still largely delocalized. Our findings suggest that the a-priori detection of plastic instabilities can be effectively carried out by the investigation of the landscape of .
Cite
@article{arxiv.1507.06931,
title = {Nonlinear plastic modes in disordered solids},
author = {Luka Gartner and Edan Lerner},
journal= {arXiv preprint arXiv:1507.06931},
year = {2016}
}
Comments
8 pages, 8 figures