Stress-induced phase transformations in Ti-15Mo alloy at elevated temperature

TL;DR

This study investigates how mechanical loading influences phase transformations in Ti-15Mo alloy during annealing at 550°C, revealing stress-induced formation of $ ext{omega}_{ ext{iso}}$ and $ ext{alpha}$ phases, which affect the alloy's microstructure and properties.

Contribution

It demonstrates that plastic deformation significantly influences phase transformations in Ti-15Mo alloy during annealing, providing insights for optimizing thermomechanical processing.

Findings

Massive $ ext{omega}_{ ext{iso}}$ phase formation occurs without external stress.

Plastic deformation promotes $eta ightarrow ext{alpha}$ transformation.

Refined microstructure improves mechanical properties.

Abstract

Controlled mechanical loading was applied to Ti-15Mo alloy during annealing at 550 $^\circ$C. Massive formation of the $\omega_{\textrm{iso}}$ phase from the parent $\beta$-phase occurred during annealing at 550 $^\circ$C without external stress or with stress well below the yield stress. Moreover, a massive $\alpha$ phase precipitation takes place under simultaneous annealing and plastic deformation. Plastic deformation plays a key role in $\beta\rightarrow\alpha$ transformation and achieving refined $\alpha+\beta$ type microstructure resulted in improved mechanical properties. Studying phase transformations during plastic deformation is critical for understanding and optimizing thermomechanical processing of metastable $\beta$-Ti alloys.