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Title:Density functional theory simulation of titanium migration and reaction with oxygen in the early stages of oxidation of equiatomic NiTi alloy
Authors:Michael Nolan, Syed A M Tofail, 2010
Abstract: The biocompatibility of NiTi shape memory alloys (SMA) has made possible applications in self-expandable cardio-vascular stents, stone extraction baskets, catheter guide wires and other invasive and minimally invasive biomedical devices. The NiTi intermetallic alloy spontaneously forms a thin passive layer of TiO2, which provides its biocompatibility. The oxide layer is thought to form as the Ti in the alloy surface reacts with oxygen, resulting in a depletion of Ti in the subsurface region – experimental evidence indicates formation of a Ni-rich layer below the oxide film. In this paper, we study the initial stages of oxide growth on the (110) surface of the NiTi alloy to understand the formation of alloy/oxide interface. We initially adsorb atomic and molecular oxygen on the (110) surface and then successively add O2 molecules, up to 2 monolayer of O2. Oxygen adsorption always results in a large energy gain. With atomic oxygen, Ti is pulled out of the surface layer leaving behind a Ni-rich subsurface region. Molecular O2, on the other hand adsorbs dissociatively and pulls a Ti atom farther out of the surface layer. The addition of further O2 up to 1 monolayer is also dissociative and results in complete removal of Ti from the initial surface layer. When further O2 is added up to 2 monolayer, Ti is pulled even further out of the surface and a single thin layer of composition O–Ti–O is formed. The electronic structure shows that the metallic character of the alloy is unaffected by interaction with oxygen and formation of the oxide layer, consistent with the oxide layer being a passivant.
ICHEC Project:First Principles Simulations of Shape Memory Alloys Based on NiTi
Publication:Biomaterials, vol. 31, p. 3439
URL: http://doi.org/10.1016/j.biomaterials.2010.01.060
Keywords: Density functional theory; NiTi; TiO2; biocompatibility; oxidation
Status: Published

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