Microplasticity and yielding in crystals with heterogeneous dislocation distribution
Xu Zhang, Jian Xiong, Haidong Fan, Michael Zaiser

TL;DR
This paper uses discrete dislocation dynamics simulations to study how heterogeneous dislocation distributions affect the elastic and plastic behavior of face-centered cubic crystals, revealing effects on elastic modulus, yield stress, and hardening.
Contribution
It introduces a continuum dislocation dynamics model to explain the transition from inversive to non-inversive dislocation motion and analyzes the impact of dislocation density gradients on deformation.
Findings
Effective elastic modulus decreases with dislocation density gradient.
Yield stress decreases as dislocation density gradient increases.
Pronounced hardening stage with stress redistribution observed.
Abstract
In this study, we use discrete dislocation dynamics (DDD) simulation to investigate the effect of heterogeneous dislocation density on the transition between quasi-elastic deformation and plastic flow in face-centered cubic single crystals. By analyzing the stress-strain curves of samples with an initial, axial dislocation density gradient, we arrive at the following conclusions: (i) in the regime of quasi-elastic deformation before the onset of plastic flow, the effective elastic modulus of the simulated samples falls significantly below the value for a dislocation-free crystal. This modulus reduction increases with decreasing dislocation density gradient: crystals with homogeneous dislocation distribution are thus weakest in the quasi-elastic regime; (ii) the transition towards plastic flow occurs first in regions of reduced dislocation density. Therefore, the overall yield stress…
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