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Resistance spot welded NiTi shape memory alloy to Ti6Al4V: Correlation between joint microstructure, cracking and mechanical properties

Yihu Zang, Jilin Xie, Yuhua Chen, Min Zheng, Xiaofang Liu, Jiajia Shen, J.P. Oliveira

2025Materials & Design35 citationsDOIOpen Access PDF

Abstract

• Dissimilar joining of NiTi SMA and Ti6Al4V by RSW was achieved, overcoming challenges posed by brittle IMCs formation. • Our study elucidates the critical relationship between crack formation, brittle phases, and mechanical properties of the joints, providing new insights into the failure mechanisms. • The formation process of the dissimilar joints by RSW is detailed, offering a detailed understanding of the microstructural evolution and phase transformations. Despite the popularity of joining NiTi and Ti6Al4V in aerospace and biomedical applications, effective solutions for their dissimilar joining are limited due to brittle intermetallic compounds. In this work, we successfully joined NiTi/Ti6Al4V using resistance spot welding. Results indicate that the number of cracks is the primary factor determining the lap-shear load. The extensive accumulation of brittle Ti 2 Ni at the bottom of the weld pool leads to stress concentration and is the main cause of crack initiation. X-ray diffraction and phase diagrams revealed the solidification sequence of liquid metal in the joint, including L → N i T i , L + N i T i → Ti 2 N i , L → β T i + Ti 2 N i . Electron backscatter diffraction analysis showed that weld nugget grains exhibited random orientation, with stress concentration mainly within the Ti 2 Ni phase on the Ti6Al4V side and at the boundary between the NiTi and Ti 2 Ni phases, contributing to high susceptibility to deformation and cracking in these regions. Nanoindentation analysis further demonstrated that the welding process diminished the superelastic performance of NiTi, attributable to Ti 2 Ni phase, grain coarsening and the orientation deviation of B2 NiTi.

Topics & Concepts

Materials scienceNickel titaniumMicrostructureShape-memory alloySpot weldingJoint (building)Titanium alloyMetallurgyWeldingCrackingComposite materialAlloyStructural engineeringEngineeringShape Memory Alloy TransformationsTitanium Alloys Microstructure and PropertiesAdvanced Welding Techniques Analysis