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Multiple deformation mechanisms induce high work hardening in Ti–5Al–7.5 V alloy via transformed β matrix

Sisi Xie, Zhihong Wu, Nana Chen, Mingxiang Zhu, Hao Yang, Zilong Zhang, Chuanyun Wang, Jinshan Li, Hongchao Kou

2024Materials Research Letters19 citationsDOIOpen Access PDF

Abstract

In this work, different transformed β matrix was obtained in Ti–5Al–7.5 V alloy. The alloy with equiaxed αp phase and transformed β matrix containing α′ martensite and β phase exhibits good combination of strength and plasticity, as well as a high work hardening rate. A concurrent operation of stress-induced α″ martensitic transformation, deformation twinning and dislocation slips was observed governing the deformation process of this alloy. The alloy with equiaxed αp phase and transformed β matrix containing secondary αs plates and retained β phase shows a high strength and plasticity but low work hardening rate, which is caused by dislocation slips.HighlightsThe quenched Ti–5Al–7.5 V alloy exhibits a high work hardening rate, approximately 5500 MPa.The dependence of work hardening rate of Ti–5Al–7.5 V alloy on transformed β matrix is revealed.Concurrent operations of stress-induced α″ martensitic transformation, deformation twinning and dislocation slips govern deformation of the studied alloy.

Topics & Concepts

Materials scienceEquiaxed crystalsAlloyWork hardeningPlasticityHardening (computing)Crystal twinningMartensiteDiffusionless transformationDeformation (meteorology)MetallurgyDislocationPhase (matter)Composite materialMicrostructureOrganic chemistryChemistryLayer (electronics)Titanium Alloys Microstructure and PropertiesIntermetallics and Advanced Alloy PropertiesAdvanced Welding Techniques Analysis