Simulation of structural phase transitions in NiTi

TL;DR

This study uses molecular dynamics simulations to investigate temperature-driven, diffusionless phase transitions in NiTi alloys, confirming the influence of composition on transition temperatures and elucidating the energetics involved.

Contribution

It introduces a simulation approach using a specific model potential to analyze phase transitions and their dependence on composition and energetics in NiTi alloys.

Findings

Predicted stable B19' phase at low temperatures.

Identified nearly cubic B2 phase at high temperatures.

Confirmed composition dependence of transition temperatures.

Abstract

By means of molecular-dynamics simulations, temperature driven diffusionless structural phase transitions in equi- and nearly equiatomic ordered nickel-titanium alloys were investigated. For this purpose, a model potential from the literature was adopted [W.S. Lai and B.X. Liu, J. Phys. Condens. Matter 12, L53 (2000)], which is based on the tight-binding model in second moment approximation. The model predicts a stable B19' phase at low temperatures and a nearly cubic B2 phase at high temperatures. After an analysis of crystallography and energetics of the emerging structures, the experimentally known strong dependence of transition temperatures on composition is confirmed and related to lattice instability. Free energy calculations finally give insight into the driving forces of the phase transitions, and reveal free energy barriers inhibiting them below the transition temperatures.