A peridynamic implementation of crystal plasticity

This paper presents the first application of peridynamics theory for crystal plasticity simulations. A state-based theory of peridynamics is used (Silling et al., 2007) where the forces in the bonds between particles are computed from stress tensors obtained from crystal plasticity. The stress tensor at a particle, in turn, is computed from strains calculated by tracking the motion of surrounding particles. We have developed a quasi-static implementation of the peridynamics theory. The code employs an implicit iterative solution procedure similar to a non-linear finite element implementation. Peridynamics results are compared with crystal plasticity finite element (CPFE) analysis for the problem of plane strain compression of a planar polycrystal. The stress, strain field distribution and the texture formation predicted by CPFE and peridynamics were found to compare well. One particular feature of peridynamics is its ability to model fine shear bands that occur naturally in deforming polycrystalline aggregates. Peridynamics simulations are used to study the origin and evolution of these shear bands as a function of strain and slip geometry.