Dislocation dynamics in polycrystalline materials
Jaehyun Cho, Joshua C. Crone, A. Arsenlis, Sylvie Aubry
Abstract
Abstract An extension of the dislocation dynamics method to polycrystalline materials is presented with emphasis on handling interactions between dislocations and grain boundaries. The key new features of the method include: (1) a grain boundary detection algorithm, (2) new dislocation emission criteria based on power dissipation and area growth, (3) mobility of dislocations at grain boundaries, and (4) extension of topological operations e.g. mesh adaption, collision, and dissociation to handle dislocations interacting with grain boundaries. Verification and validation examples are executed to compare our calculations with existing analytic methods, molecular dynamics simulations, and experimental observations.