Improved fatigue properties with maintaining low Young's modulus achieved in biomedical beta-type titanium alloy by oxygen addition

Oxygen was added into biomedical β-type Ti-29Nb-13Ta-4.6Zr (mass%, TNTZ) alloy to improve its fatigue properties with maintaining its low Young's modulus. The effect of oxygen on the fatigue behaviors of these oxygen-added TNTZ alloys was systematically investigated. A series of TNTZ-(0.1, 0.3,...

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Bibliographic Details
Published in:Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2017-09, Vol.704, p.10-17
Main Authors: Liu, Huihong, Niinomi, Mitsuo, Nakai, Masaaki, Obara, Shinya, Fujii, Hidetoshi
Format: Article
Language:English
Subjects:
Alloy systems
Alloying additive
Alloys
Biocompatibility
Biomaterials
Biomedical materials
Characterization
Crack initiation
Crack propagation
Elongation
Fatigue
Fatigue failure
Fatigue limit
Fracture mechanics
Martensite
Modulus of elasticity
Oxygen
Oxygen content
Surgical implants
Tensile strength
Titanium alloys
Titanium base alloys
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Summary:Oxygen was added into biomedical β-type Ti-29Nb-13Ta-4.6Zr (mass%, TNTZ) alloy to improve its fatigue properties with maintaining its low Young's modulus. The effect of oxygen on the fatigue behaviors of these oxygen-added TNTZ alloys was systematically investigated. A series of TNTZ-(0.1, 0.3, 0.5 and 0.7 mass%)O alloys were prepared, denoted as 0.1O, 0.3O, 0.5O, and 0.7O, respectively. The Young's moduli of the prepared alloys increase slightly with increasing oxygen content; 0.7O possessing the highest oxygen content still shows a quite low Young's modulus. The fatigue limits of the alloys increase monotonically with oxygen content increases. The high-concentration oxygen in 0.7O suppresses the slip plane decohesion and induces the formation of densely-arranged small-scaled α" martensite twins that increases the paths and distance for fatigue crack propagation, thus it enhances the resistance to the fatigue crack initiation and propagation in 0.7O, which contributes to its excellent fatigue performance. Among all the alloys compared in the present study, 0.7O shows a high fatigue limit of ~ 635MPa, a high tensile strength of ~ 1100MPa, a large elongation of ~ 20% as well as a low Young's modulus of ~ 76GPa, thus it is regarded as a promising biomaterial for next-generation biomedical applications.
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2017.07.078