Interplay between Nucleation and Kinetics in Dynamic Twinning

TL;DR

This paper uses a phase-field model to explore how nucleation and kinetics influence the dynamic evolution of twinning interfaces, revealing the importance of explicit kinetic and nucleation behavior in predicting twin growth.

Contribution

It introduces a phase-field modeling framework that explicitly specifies nucleation and kinetic behaviors, enabling detailed study of twin evolution and growth mechanisms.

Findings

Twin nucleation occurs ahead of moving interfaces due to finite velocity and stress relaxation.

Both nucleation and anisotropic kinetics are crucial for accurate prediction of needle twin growth.

Standard models lack the ability to specify anisotropic kinetics explicitly, unlike the phase-field approach.

Abstract

In this work, we apply a phase-field modeling framework to elucidate the interplay between nucleation and kinetics in the dynamic evolution of twinning interfaces. The key feature of this phase-field approach is the ability to transparently and explicitly specify nucleation and kinetic behavior in the model, in contrast to other regularized interface models. We use this to study 2 distinct problems where it is essential to explicitly specify the kinetic and nucleation behavior governing twin evolution. First, we study twinning interfaces in 2-d. When these interfaces are driven to move, we find that significant levels of twin nucleation occur ahead of the moving interface. Essentially, the finite interface velocity and the relaxation time of the stresses ahead of the interface allows for nucleation to occur before the interface is able to propagate to that point. Second, we study the growth of needle twins in antiplane elasticity. We show that both nucleation and anisotropic kinetics are essential to obtain predictions of needle twins. While standard regularized interface approaches do not permit the transparent specification of anisotropic kinetics, this is readily possible with the phase-field approach that we have used here.