Abstract
Wear resistant ceramic coatings were generated on novel commercially pure titanium grade 4+ alloys by the plasma electrolytic oxidation technique (PEO) in an aluminate and zirconia containing electrolyte. The coatings were obtained adopting a full regular two-level factorial design of experiments (DoE) varying the PEO process parameters current density, repetition rate and duty cycle. The generated coatings were characterized with respect to its wear resistance and mechanical properties by reciprocal ball-on-flat tests and nanoindentation measurements. Thickness, morphology and phase formation of the PEO coatings was analyzed by scanning electron microscopy (SEM/EDS) and X-ray diffraction. XRD results indicate the formation of crystalline aluminium titanate (TiAlO) as well as t-ZrO and alumina leading to an increase in hardness and wear resistance of the PEO coatings. Evaluation of the DoE’s parameter interaction shows that the main effects for generating wear resistant coatings are current density and repetition rate. In particular, the formation of mechanically stable and adhesive corundum and zirconia containing coatings with increasing current density and frequency turned out to be responsible for the improvement of the tribological properties. Overall, the PEO processing significantly improves the wear resistance of the CP titanium base alloy.
Highlights
Titanium and its alloys have been used as common materials for biomedical implant technologies for several decades, due to their good mechanical properties, corrosion resistance and satisfying biocompatibility [1,2,3]
Plasma electrolytic oxidation on CP titanium grade 4+ materials exhibits significantly improved wear properties compared to the base material
The main effects for the generation of wear-resistant coatings in terms of the varied parameters can be identified as the current density and repetition rate
Summary
Titanium and its alloys have been used as common materials for biomedical implant technologies for several decades, due to their good mechanical properties, corrosion resistance and satisfying biocompatibility [1,2,3]. The interaction of wear and corrosion (tribocorrosion) may lead to a progressive degradation of the material [6]. Harmful metal ions such as aluminium or vanadium or even abraded nanoparticles can be released into the human body and lead to implant failure [7,8]. For this reason, new aluminium and vanadium-free titanium alloys are being developed [9,10]. The developed alloys are required to meet the mechanical properties of the current standard alloy Ti Al6 V4 [10]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
