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Damage accumulation and its effect during thermal- and stress-induced cycling martensite transformation of laser powder bed fused (LPBF) NiTi alloy

Qian Zhang, Wenwen Sun, Meng Gao, Yitao Liu, Shijie Hao, L.S. Cui, Luquan Ren, Zhihui Zhang

2024International Journal of Fatigue11 citationsDOIOpen Access PDF

Abstract

Nitinol (NiTi) alloys produced via laser powder bed fusion (LPBF) exhibit promising potential across diverse applications, yet their suitability for devices necessitating repetitive actuation confronts uncertainties regarding microstructural evolution and functional fatigue behavior during cyclic operation. Our investigation unveils that damage accumulation during thermal cycling stems from geometrically necessary dislocations formed through finite-scale incoherent interface motion, contrasting earlier hypotheses attributing LPBF-induced dislocation activity as the primary contributor. Damage accumulation during mechanical cycling is characterized by notable multiplication of cyclic dislocations via dislocation twinning interactions, rather than severe martensitic plasticity. These newborn cycling dislocations inherit martensite's crystallographic characteristics, exerting a distinct influence mechanism on martensite transformation and deformation behavior, diverging from conventional studies on function fatigue in traditional NiTi alloys. This study sheds light on the distinctive damage accumulation traits observed during thermal/mechanical cycling of LPBF-fabricated NiTi alloys, offering valuable insights for probing their functional fatigue mechanisms.

Topics & Concepts

Nickel titaniumMaterials scienceTemperature cyclingMetallurgyMartensiteAlloyShape-memory alloyTransformation (genetics)Stress (linguistics)CyclingDiffusionless transformationThermalComposite materialMicrostructureChemistryThermodynamicsBiochemistryPhilosophyGenePhysicsHistoryLinguisticsArchaeologyShape Memory Alloy TransformationsTitanium Alloys Microstructure and PropertiesHigh Entropy Alloys Studies
Damage accumulation and its effect during thermal- and stress-induced cycling martensite transformation of laser powder bed fused (LPBF) NiTi alloy | Litcius