Phase-field modeling of multivariant martensitic transformation at finite-strain: Computational aspects and large-scale finite-element simulations

Large-scale 3D martensitic microstructure evolution problems are studied using a finite-element discretization of a finite-strain phase-field model. The model admits an arbitrary crystallography of transformation and arbitrary elastic anisotropy of the phases, and incorporates Hencky-type elasticity, a penalty-regularized double-obstacle potential, and viscous dissipation. The finite-element discretization of the model is performed in Firedrake and relies on the PETSc solver library. The large systems of linear equations arising are efficiently solved using GMRES and a geometric multigrid preconditioner with a carefully chosen relaxation. The modeling capabilities are illustrated through a 3D simulation of the microstructure evolution in a pseudoelastic CuAlNi single crystal during nano-indentation, with all six orthorhombic martensite variants taken into account. Robustness and a good parallel scaling performance have been demonstrated, with the problem size reaching 150 million degrees of freedom. (C) 2021 Elsevier B.V. All rights reserved.

Automated summary

This study investigates large-scale 3D martensitic microstructure evolution problems using a finite-element discretization of a finite-strain phase-field model. The model incorporates various crystallography of transformation and elastic anisotropy of the phases, and demonstrates robustness and good parallel scaling performance in a 3D simulation of microstructure evolution during nano-indentation. The finite-element discretization relies on the PETSc solver library and efficiently solves the large systems of linear equations arising from the model.