Effect of high-energy implantation on TAFe titanium alloy

Implantation of non-metallic ions in transition metals such as titanium typically forms high-melting phases at low temperatures. In this work, we study the effect of N + implantation into a specific titanium alloy (Ti–5 wt.% Al–2.5 wt.% Fe) recently used for orthopedic prostheses. High-dose (10 18 a...

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Bibliographic Details
Published in:Surface & coatings technology 2002-03, Vol.151, p.42-46
Main Authors: Pelletier, H., Müller, D., Mille, P., Cornet, A., Grob, J.J.
Format: Article
Language:English
Subjects:
Annealing process
Implantation
Nano-indentation
Titanium alloy
XRD
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Summary:Implantation of non-metallic ions in transition metals such as titanium typically forms high-melting phases at low temperatures. In this work, we study the effect of N + implantation into a specific titanium alloy (Ti–5 wt.% Al–2.5 wt.% Fe) recently used for orthopedic prostheses. High-dose (10 18 at cm −2) nitrogen implantation at 1 MeV was performed. Specimens were held at a constant temperature ( T imp=−30 °C) and the current density was fixed at 1.5 μA cm −2 to avoid heating and fast diffusion processes during treatment. Nano-indentation results show small effects on mechanical properties, especially on hardness (with Δ H/ H=35%) and elastic modulus (with Δ E/ E less than 10%). Grazing incidence X-ray diffraction results indicate the formation of titanium nitrides TiN 0.3. Samples have been annealed for 1 and 3 h at different temperatures in an argon atmosphere to enhance the nitriding process. At low temperature (350 °C) no evolution of hardness profiles are observed. However, at high temperature (500 °C), a significant increase of the hardness in the near surface region ( H=12 GPa) and at a specific indentation depth ( H=8.5 GPa) are detected. These variations are respectively correlated with the formation of a thin oxide film (TiO 2) and a layer composed of a mixture of titanium nitrides (TiN+Ti 2N) around the ion range. This study shows that the implanted sample can be divided into different layers corresponding to different nitride species as a function of nitrogen concentration distribution.
ISSN:0257-8972
1879-3347
DOI:10.1016/S0257-8972(01)01597-3