4.5 Article

Biomedical NiTi and β-Ti Alloys: From Composition, Microstructure and Thermo-Mechanics to Application

Journal

METALS
Volume 12, Issue 3, Pages -

Publisher

MDPI
DOI: 10.3390/met12030406

Keywords

titanium alloy; shape-memory alloy; microstructure; structure-property relationship; phase transformation; composition; phase-stabilizing element

Funding

  1. Natural Sciences and Engineering Research Council (NSERC), Canada [RGPIN 04598]

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A comprehensive characterization of widely used biomedical Ti-containing alloys, NiTi and beta-Ti, was conducted to understand the relationship between their composition, microstructure, physical-chemical-mechanical properties and processing history. The results provided insights into the influence of alloying elements and thermo-mechanical processing on microstructure and phase composition of beta-Ti, as well as the phase transformation behavior of NiTi.
A comprehensive, bottoms-up characterization of two of the most widely used biomedical Ti-containing alloys, NiTi and beta-Ti, was carried out applying a novel combination of neutron diffraction, neutron prompt-gamma activation, surface morphology, thermal analysis and mechanical tests, to relate composition, microstructure and physical-chemical-mechanical properties to unknown processing history. The commercial specimens studied are rectangular (0.43 x 0.64 mm similar to 0.017 x 0.025 inch) wires, in both pre-formed U-shape and straight extended form. Practical performance was quantitatively linked to the influence of alloying elements, microstructure and thermo-mechanical processing. Results demonstrated that the microstructure and phase composition of beta-Ti strongly depended on the composition, phase-stabilizing elements in particular, in that the 10.2 wt.% Mo content in Azdent resulted in 41.2% alpha phase, while Ormco with 11.6 wt.% Mo contained only beta phase. Although the existence of alpha phase is probable in the meta-stable alloy, the alpha phase has never been quantified before. Further, the phase transformation behavior of NiTi directly arose from the microstructure, whilst being highly influenced by thermo-mechanical history. A strong correlation (r = 0.878) was established between phase transformation temperature and the force levels observed in bending test at body temperature, reconfirming that structure determines performance, while also being highly influenced by thermo-mechanical history. The novel methodology described is evidenced as generating a predictive profile of the eventual biomechanical properties and practical performance of the commercial materials. Overall, the work encompasses a reproducible and comprehensive approach expected to aid in future optimization and rational design of devices of metallic origin.

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