Solitonic State in Microscopic Dynamic Failures

TL;DR

This paper reveals that solitons, or local excitations, play a key role in the microscopic failure process of crystalline materials under indentation, influencing the dynamics of defect propagation and failure.

Contribution

It demonstrates the formation, interaction, and acceleration of solitons during material failure, linking microscopic defect dynamics to macroscopic failure behavior.

Findings

Solitons are involved in the failure process of crystalline materials.

Accelerations of solitons shorten the fast-slip phase.

Soliton interactions lead to non-Newtonian behavior and Lorentz contraction.

Abstract

Onset of permanent deformation in crystalline materials under a sharp indenter tip is accompanied by nucleation and propagation of defects. By measuring the spatio-temporal strain field nearthe indenter tip during indentation tests, we demonstrate that the dynamic strain history at the moment of a displacement burst carries characteristics of formation and interaction of local excitations, or solitons. We show that dynamic propagation of multiple solitons is followed by a short time interval where the propagating fronts can accelerate suddenly. As a result of such abrupt local accelerations, duration of the fast-slip phase of a failure event is shortened. Our results show that formation and annihilation of solitons mediate the microscopic fast weakening phase, during which extreme acceleration and collision of solitons lead to non-Newtonian behavior and Lorentz contraction, i.e., shortening of solitons characteristic length. The results open new horizons for understanding dynamic material response during failure and, more generally, complexity of earthquake sources.