Application of Rigorous Interface Boundary Conditions in Mesoscale Plasticity Simulations

TL;DR

This paper introduces a physically realistic interface boundary condition based on Burgers vector conservation, unifying various mesoscale plasticity simulation methods and improving the fidelity of grain boundary modeling.

Contribution

It presents a new interface boundary condition that can be integrated into multiple simulation approaches, enhancing physical accuracy and consistency across models.

Findings

Boundary condition is compatible with multiple simulation methods.

Simulations show improved agreement with experimental data.

The approach enables multiscale modeling of dislocation-interface interactions.

Abstract

The interactions between dislocations and interface/grain boundaries, including dislocation absorption, transmission, and reflection, have garnered significant attention from the research community for their impact on the mechanical properties of materials. However, the traditional approaches used to simulate grain boundaries lack physical fidelity and are often incompatible across different simulation methods. We review a new mesoscale interface boundary condition based on Burgers vector conservation and kinetic dislocation reaction processes. The main focus of the paper is to demonstrate how to unify this boundary condition with different plasticity simulation approaches such as the crystal plasticity finite element, continuum dislocation dynamics, and discrete dislocation dynamics methods. To validate our interface boundary condition, we implemented simulations using both the crystal plasticity finite element method and a two-dimensional continuum dislocation dynamics model. Our results show that our compact and physically realistic interface boundary condition can be easily integrated into multiscale simulation methods and yield novel results consistent with experimental observations.