On the yielding of a defect-rich model crystal under shear: insights from molecular dynamics simulations

TL;DR

This study uses molecular dynamics simulations to investigate how defect-rich cluster crystals yield under shear, revealing that yielding primarily involves structural deformation regardless of particle diffusion timescales.

Contribution

It provides new insights into the yielding behavior of defect-rich crystals, showing that plastic deformation dominates over diffusion effects across various shear rates and temperatures.

Findings

Yielding involves plastic deformation of the crystal structure.

Diffusion timescales do not significantly alter the yielding mechanism.

Structural changes are confirmed by bond order parameters and local angles.

Abstract

Point defects in real crystals at finite temperatures are inevitable. Their dynamics severely influence the mechanical properties of crystals under shear giving rise to nonlinear effects such as ductility. Therefore, it is crucial to explore the interplay of the equilibrium point-defect diffusion timescales and shear-induced timescales to understand the plastic deformation of crystals. Using extensive nonequilibrium molecular dynamics simulations, we present a study on the yielding behavior of cluster crystals (CC), an archetypal model for defect-rich crystals where the crystalline structure is characterized by multiple occupancies (cluster) of particles at a lattice site. In equilibrium, particles diffuse via site-to-site hopping keeping the crystalline structure intact. We consider the CCs at a fixed density and different temperatures where it remains in the FCC structure, and the diffusion timescales of particles vary depending on the temperature. We choose the range of shear rates, which covers timescales higher and much lower than the equilibrium diffusion timescales at high temperatures. For the considered range of shear rates and temperatures, both the macro and microscopic responses of CCs to the shear suggest that the yielding scenario remains independent of the diffusion of particles. It involves the plastic deformation of the underlying crystalline structure. The averaged local bond order parameters and local angle measurements demonstrate the structural changes and cooperative movement of the center of masses of the clusters close to the yield point. A comparison with the soft-sphere (SS) FCC crystal reveals the similarities in the yielding behavior of both systems. Nonetheless, diffusion of particles influences certain features, such as a less prominent increase in the local bond order parameters and local angles close to the yield point.