Abstract
Nanocrystalline TiO2 coatings were produced on titanium substrates using the plasma electrolytic oxidation technique. The effects of frequency, duty cycle, and type of applied current (pulse and direct) were evaluated on the microstructure of the coatings and the tribological behavior of the samples. Morphological evaluations demonstrated that the pancake structure was developed from coatings created with a unipolar pulsed current. However, a volcano-like surface morphology resulted from a constant current. The XRD analysis results showed that the coatings were composed mainly of the rutile phase by 77.80-96.34 wt. %. In comparison, 22.20 wt. % of the anatase phase was identified in samples produced with direct current. These phases were determined to be nanocrystalline (29.5-48.3 nm), which led to significant improvements in the tribological properties. The sample produced with direct current had larger pores, greater roughness, and a four-times higher thickness than samples created with unipolar current. Furthermore, the tribological study results showed that wear resistance was significantly higher in the unipolar pulsed current coatings than in those obtained with direct current. Moreover, samples made at a higher frequency and lower duty cycle showed better tribological behavior.
Highlights
Pure titanium (Ti) and titanium alloys have been extensively used in the aerospace, automotive, marine, medical, and energy industries
We evaluated the effects of frequency, duty cycle, and applied current on the wear characteristics of nanocrystalline TiO2 coatings produced with plasma electrolytic oxidation (PEO) in a carbonate electrolyte with different frequencies and duty cycles
In the B3 sample, voltage instantaneously increased, which might be because direct current was used, and the current reached the breakdown zone [18]
Summary
Pure titanium (Ti) and titanium alloys have been extensively used in the aerospace, automotive, marine, medical, and energy industries. Ti and its alloys have some desirable properties, including low density, low elastic modulus, high strength-to-weight ratio, high melting point, and great biocompatibility, as well as good corrosion, creep, and fatigue resistance [1, 2]. Ti has some disadvantages, including high friction coefficient, low abrasive, low adhesive wear resistance (weak tribological properties) [3,4,5]. To increase the Ti wear resistance, TiO2 is commonly used as a covering. To deposit TiO2 coating on the Ti surface, various surface modifying techniques classified as physical, chemical, and electrochemical methods have been used [6,7,8]. The newest electrochemical coating process is generally known as plasma electrolytic oxidation (PEO) [9, 10]
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