Role of point defects in stress-induced martensite transformations in NiTi shape memory alloys: A molecular dynamics study
Chao Yang, Janelle P. Wharry
Abstract
Shape-memory properties of equiatomic NiTi rely on the thermal- or stress-induced reversible martensitic phase transformation between the $B2$ and $B{19}^{\ensuremath{'}}$ phases. Irradiation defects suppress thermal-induced transformations, but their effects on stress-induced transformations are poorly understood. We use molecular dynamics to investigate the effect of vacancies, vacancy clusters, interstitials, and antisite defects on stress-induced transformations. All defects suppress the transformation, but vacancy clusters do so to the greatest extent, while antisite defects do so to the least extent. The responsible mechanisms are grain boundary pinning and chemical disordering.
Topics & Concepts
Materials scienceShape-memory alloyNickel titaniumCrystallographic defectMartensiteVacancy defectGrain boundaryMolecular dynamicsDiffusionless transformationCondensed matter physicsStress (linguistics)Phase (matter)ThermalTransformation (genetics)Chemical physicsCrystallographyMicrostructureMetallurgyThermodynamicsComputational chemistryPhysicsChemistryGenePhilosophyLinguisticsQuantum mechanicsBiochemistryShape Memory Alloy TransformationsFerroelectric and Piezoelectric MaterialsHigh-pressure geophysics and materials