Synthesis, corrosion and wear of anodic oxide coatings on Ti–6Al–4V

## Abstract Si‐incorporated diamond‐like carbon (Si‐DLC) coatings ranging from 0 to 2 at % Si were deposited on Ti‐alloy substrate by means of radio frequency plasma‐assisted chemical vapor deposition (r.f. PACVD) technique, using a mixture of benzene (C~6~H~6~) and silane (SiH~4~) as the reaction

## Abstract Anodic TiO coatings were produced on Ti–6Al–4V substrates using aqueous electrolytes containing dissolved calcium and phosphorus. Two baths containing Ca and P compounds, in the molar ratios 5 and 15 were used. Different coatings were produced by electrolysis for 3 and 10 h at a constan

Wear-accelerated corrosion rates at constant anodic potentials were evaluated for unimplanted and nitrogen-ion-implanted surgical Ti-6A1-4V while wearing against ultrahigh-molecular-weight polyethylene at stress levels up to 6.90 MPa (1000 psi). The ion implantation processing was found to reduce th

The influence of nitrogen-ion implantation on the wear-accelerated corrosion behavior of surgical Ti-6A1-4V was studied. Nonpassivated and prepassivated unimplanted Ti-6A1-4V specimens were employed as controls for comparison. Corrosion rates as a function of time at open-circuit corrosion potential

Ti‐6Al‐4V alloy has attracted increasing applications as a metallic biomaterial in recent years thanks to its good corrosion resistance and biocompatibility. However, the poor corrosion‐wear resistance of the alloy is thus a major concern to potential users. In this paper, the electrochemical noise