Progress in Severe Plastic Deformation of Metastable Beta Ti Alloys

Abstract: Metastable β Ti alloys can undergo martensitic transformation under stress. It is shown that such stress‐induced martensitic transformation (SIMT) can significantly facilitate grain refinement by severe plastic deformation (SPD), achieving β grain sizes of <50 nm, compared with >100 nm in β Ti alloys without SIMT. The martensitic α″ formed partitions the β grains and blocks dislocation movement, but undergoes reverse transformation back into β at large strains, leaving a pure β grain structure. The grain refin… Show more

“…During the HPT processing of the low-modulus β -Ti alloy Ti-15Mo, a decrease in the size of β -grains/subgrains to 80 nm is observed, and the ω -phase appears at the early stages of HPT. In some β -Ti alloys of the Ti-Mo and Ti-Nb-Zr system grain refinement to 50 nm was revealed during HPT processing, while the alloys remained predominantly in the β -phase [13] , [14] , [15] , [16] .…”

Effect of HPT and accumulative HPT on structure formation and microhardness of the novel Ti18Zr15Nb alloy

“…During the HPT processing of the low-modulus β -Ti alloy Ti-15Mo, a decrease in the size of β -grains/subgrains to 80 nm is observed, and the ω -phase appears at the early stages of HPT. In some β -Ti alloys of the Ti-Mo and Ti-Nb-Zr system grain refinement to 50 nm was revealed during HPT processing, while the alloys remained predominantly in the β -phase [13] , [14] , [15] , [16] .…”

Effect of HPT and accumulative HPT on structure formation and microhardness of the novel Ti18Zr15Nb alloy

Comprehensive review of biological response, alloy design, strengthening mechanisms, performance evaluation, and surface modifications of titanium alloys for biomedical applications

Phase transformation mediated anomalous plasticity of titanium under severe loading conditions