3D Coupled Thermo-Mechanical Phase-Field Modeling of Shape Memory Alloy Dynamics via Isogeometric Analysis

TL;DR

This paper introduces an isogeometric analysis approach to simulate 3D thermo-mechanical phase transformations in shape memory alloys, effectively capturing microstructure evolution and dynamic behavior with high accuracy.

Contribution

It presents a novel application of isogeometric analysis using NURBS for solving complex fourth-order phase-field equations in 3D SMA modeling, addressing numerical challenges.

Findings

Successfully simulates microstructure evolution in SMA nanostructures.

Accurately captures thermo-mechanical behavior observed experimentally.

Demonstrates geometrical flexibility and robustness of the method.

Abstract

The paper focuses on numerical simulation of the phase-field (PF) equations for modeling martensitic transformations in shape memory alloys (SMAs), their complex microstructures and thermo-mechanical behavior. The PF model is based on the Landau-Ginzburg potential for the 3D cubic-to-tetragonal phase transformations in SMAs. The treatment of domain walls as diffuse interfaces, leads to a fourth-order differential equation in a strain-based order parameter PF model. The fourth-order equations introduce a number of unexplored numerical challenges because traditional numerical schemes have been primarily applied to second-order problems. We propose isogeometric analysis (IGA) as a numerical formulation for a straightforward solution to the fourth-order differential PF equations using continuously differentiable non-uniform rational B-splines (NURBS). We present microstructure evolution in different geometries of SMA nanostructures under temperature-induced phase transformations to illustrate the geometrical flexibility, accuracy and robustness of our approach. The simulations successfully capture the dynamic thermo-mechanical behavior of SMAs observed experimentally.