Crystal Plasticity (CP) modeling is a powerful and well established computational materials
science tool to investigate mechanical structure–property relations in crystalline materials. It …

This paper reviews recent studies, that not only includes both experiments and modeling
components, but celebrates a close coupling between these techniques, in order to provide …

The bridge between classical continuum plasticity and crystal plasticity is becoming
narrower with continuously improved computational power and with engineers' desire to …

A physically-informed continuum crystal plasticity model is presented to elucidate
deformation mechanisms, dislocation evolution and the non-Schmid effect in body-centered …

An implementation of the crystal plasticity theory in the context of the multiphase-field
method provides a numerically efficient tracking of evolving grain boundaries, modeled as …

Modeling dislocation multiplication due to interaction and reactions on a mesoscopic scale
is an important task for the physically meaningful description of stage II hardening in face …

Materials are often heterogeneous at various length scales, with variations in grain structure,
defects, and composition which has a strong influence on the emergent macroscopic plastic …

Using a partitioned-energy thermodynamic framework which assigns energy to that of
atomic configurational stored energy of cold work and kinetic-vibrational, we derive an …

Stressed dislocation pattern formation in crystal plasticity at finite deformation is
demonstrated for the first time. Size effects are also demonstrated within the same …

Modeling the deformation behavior of polycrystalline materials using the information
embedded at grain level is a recent research area of high interest. In view of this, an attempt …