From plastic flow to brittle fracture: role of microscopic friction in amorphous solids

TL;DR

This paper investigates how microscopic friction influences the transition from plastic flow to brittle fracture in amorphous solids, highlighting the nucleation of micro shear cracks and the role of frictional resistance in failure modes.

Contribution

It introduces the role of microscopic friction in altering deformation mechanisms, leading to a transition from collective plasticity to fracture-like failure in amorphous materials.

Findings

Frictional interactions nucleate micro shear cracks.

Friction controls the plastic-to-brittle transition.

Failure mode depends on frictional resistance.

Abstract

Plasticity in soft amorphous materials typically involves collective deformation patterns that emerge upon intense shearing. The microscopic basis of amorphous plasticity has been commonly established through the notion of "Eshelby"-type events, localized abrupt rearrangements that induce flow in the surrounding material via non-local elastic-type interactions. This universal mechanism in flowing disordered solids has been proposed despite their diversity in terms of scales, microscopic constituents, or interactions. However, we argue that the presence of frictional interactions in granular solids alters the dynamics of flow by nucleating micro shear cracks that continually coalesce to build up system-spanning fracture-like formations on approach to failure. The plastic-to-brittle failure transition is uniquely controlled by the degree of frictional resistance which is in essence similar to the role of heterogeneities that separate the abrupt and smooth yielding regimes in glassy structures.