Effect of Low Temperature Aging on Superelastic Behavior in Biocompatible β TiNbSn Alloy

Abstract

Superelasticity of β Ti-16 at%Nb-4.8 at%Sn alloy consisting of non- (or minimal-) cytotoxic elements was investigated for biomedical applications as functions of deformation temperature and aging heat treatment after quenching. As-quenched Ti-16Nb-4.8Sn having A_f (the reverse martensitic transformation finish temperature) of 266 K exhibits superelasticity at human body temperature (310 K) with an elastic recovery strain of 3.2%. A_f decreases with increasing aging temperature in the range of 353 to 423 K or with increasing aging time at 423 K. It is confirmed from TEM observation and Young’s modulus measurements that ω transformation occurs on aging at 423 K for 500 h. Stress for inducing martensitic transformation, σ_M, increases with aging. Stress-strain curves showing superelasticity are quite similar to each other when as-quenched or aged samples are deformed at such temperatures that they have the same σ_M. It is concluded that maximum superelastic recovery strain can be obtained at intended temperature, e.g. human body temperature, in β Ti-Nb-Sn alloys by aging at relatively low temperatures.