Improved mechanical properties of biomedical ZrNbHf alloy induced by oxidation treatment

Abstract

Abstract The effects of air oxidation upon the kinetics and mechanical properties of ZrNbHf alloy were studied in the temperature range of 550–650 °C. The oxidation kinetics derived from the weight gain measurements showed a parabolic rate law and an oxidation breakdown behavior transforming from a parabolic to linear rate law observed at 650 °C. The microstructure analysis indicates that the oxide layer consists of both monoclinic and tetragonal ZrO2 and undergoes a transformation between t-ZrO2 and m-ZrO2 with increasing oxidation time, which is an important reason for kinetics transition. The mechanical property examination presents that the oxidation treatment brings about a nearly fourfold increase in the surface hardness with a protective thickness limit of 4–6 μm. Most interestingly, the hardened surface oxide layer brings about a nearly 70 MPa increase in yield strength and a slight decrease in tensile elongation under true stress–strain conditions. The present study reports on an optimized oxidation process designed to obtain a protective and hardened ZrO2 film for biomedical ZrNbHf alloy with higher performance.