http://sistemas.eel.usp.br/docentes/arquivos/2166002/1234Nb/Geetha-review2009.pdf

Ti based biomaterials, the ultimate choice for orthopaedic implants – A review

The elastic properties, elastic models and elastic perspectives of metallic glasses

Review on titanium and titanium based alloys as biomaterials for orthopaedic applications.

Diffusion in the Ti–Al system

A new look at biomedical Ti-based shape memory alloys

Quaternary Ti–(20–26)Nb–(2–8)Zr–(3.5–11.5)Sn (wt%) alloys were investigated to evaluate the effects of Zr and Sn on Young's modulus and superelasticity of Ti–Nb-based alloys. X-ray diffraction analysis showed that solution-treated alloys have β + α″, β + ω, α″ + ω, α″, or β microstructures. Zr and Sn increase the lattice parameters of the β phase; for orthorhombic α″ matensite, they increase the lattice parameter a but decrease both b and c . The martensitic start temperature of the α″ is depressed by Zr and Sn additions, whereas the formation of athermal ω is dependent on Zr and Sn contents. Differential scanning calorimetry (DSC) measurements show that 1 wt% of Nb, Zr or Sn addition decreases the martensitic start temperature by 17.6, 41.2 or 40.9 K, respectively, due to their negative effect on lattice parameter ratios of the martensite ( c / a and b / a ). Tensile tests were used to evaluate Young's modulus and superelasticity of the solution-treated alloys. Of the studied alloys Ti–24Nb–4Zr–7.5Sn with single β microstructure has the lowest Young's modulus of 52 GPa and recoverable elastic strain of about 2% at room temperature after cyclic strain.

http://www.fem.unicamp.br/~giorgia/Hao%202006.pdf

Effect of Zr and Sn on Young's modulus and superelasticity of Ti-Nb-based alloys

Here we report a non-toxic β-type titanium alloy exhibiting unstable elastic and plastic deformation behavior. Elastic instability leads to remarkable elastic softening, i.e., the decrease of incipient Young’s modulus with slight pre-straining. In spite of partial recovery during room-temperature aging, a stable modulus of 33GPa matching that of human bone can be maintained. Plastic instability causes highly-localized deformation which is very effective in grain refinement but contributes little to strength. We thus obtain soft nanostructured metallic materials (NMMs): The flow stress increases by only ∼5.5% as coarse grains are reduced to below 50nm, in contrast with several times increase for previously-reported NMMs.

Super-elastic titanium alloy with unstable plastic deformation

We report a ductile beta-type titanium alloy with body-centered cubic (bcc) crystal structure having a low Poisson's ratio of 0.14. The almost identical ultralow bulk and shear moduli of similar to 24 GPa combined with an ultrahigh strength of similar to 0.9 GPa contribute to easy crystal distortion due to much-weakened chemical bonding of atoms in the crystal, leading to significant elastic softening in tension and elastic hardening in compression. The peculiar elastic and plastic deformation behaviors of the alloy are interpreted as a result of approaching the elastic limit of the bcc crystal under applied stress.

/pdf/ductile-titanium-alloy-with-low-poisson-s-ratio-1luhhwdbpr.pdf

Y. L. Hao

Papers

Effect of Zr and Sn on Young's modulus and superelasticity of Ti-Nb-based alloys

Super-elastic titanium alloy with unstable plastic deformation

Ductile titanium alloy with low Poisson's ratio.

The site occupancies of alloying elements in TiAl and Ti3Al alloys

Formation and growth of calcium phosphate on the surface of oxidized Ti-29Nb-13Ta-4.6Zr alloy.