Mechanical properties and microstructure of powder metallurgy Ti–xNb–yMo alloys for implant materials

Abstract

In this study, a series of Ti–xNb–yMo (x=5–40wt.% in 5wt.% increments; and y=3, 5, 10 wt.%) alloys were fabricated by powder metallurgy and studied with respect to their microstructures, compressive mechanical properties and hardness. Increases in Nb and Mo content led to decreases in compressive and yield strengths, elastic modulus and hardness of the sintered alloys. Among the studied alloys, Ti–10Nb–3Mo alloy exhibited the optimum combination of strength and ductility. Alloys with a lower amount of Nb (≤25wt.%) and Mo (≤5wt.%) developed Widmanstätten structure, while further increase in Nb and Mo additions led to the microstructure predominantly consisting of β phase with varying regions of α+β phase. The effects of sintering temperature on elastic modulus and hardness were also investigated for Ti–xNb–3Mo alloys.