Abstract
This study investigated the electrochemical behavior of chromium nano-carbide cermet coating applied on Ti–6Al–4V and Co–Cr–Mo alloys for potential application as wear and corrosion resistant bearing surfaces. The cermet coating consisted of a highly heterogeneous combination of carbides embedded in a metal matrix. The main factors studied were the effect of substrate (Ti–6Al–4V vs. Co–Cr–Mo), solution conditions (physiological vs. 1 M H 2O 2 of pH 2), time of immersion (1 vs. 24 h) and post coating treatments (passivation and gamma sterilization). The coatings were produced with high velocity oxygen fuel (HVOF) thermal spray technique at atmospheric conditions to a thickness of 250 μm then ground and polished to a finished thickness of 100 μm and gamma sterilized. Native Ti–6Al–4V and Co–Cr–Mo alloys were used as controls. The corrosion behavior was evaluated using potentiodynamic polarization, mechanical abrasion and electrochemical impedance spectroscopy under physiologically representative test solution conditions (phosphate buffered saline, pH 7.4, 37 °C) as well as harsh corrosion environments (pH ∼ 2, 1 M H 2O 2, T = 65 °C). Severe environmental conditions were used to assess how susceptible coatings are to conditions that derive from possible crevice-like environments, and the presence of inflammatory species like H 2O 2. SEM analysis was performed on the coating surface and cross-section. The results show that the corrosion current values of the coatings (0.4–4 μA/cm 2) were in a range similar to Co–Cr–Mo alloy. The heterogeneous microstructure of the coating influenced the corrosion performance. It was observed that the coating impedances for all groups decreased significantly in aggressive environments compared with neutral and also dropped over exposure time. The low frequency impedances of coatings were lower than controls. Among the coated samples, passivated nanocarbide coating on Co–Cr–Mo alloy displayed the least corrosion resistance. However, all the coated materials demonstrated higher corrosion resistance to mechanical abrasion compared to the native alloys.
Highlights
The coated materials demonstrated higher corrosion resistance to mechanical abrasion compared to the native alloys
At the end of 1 hr immersion in phosphate buffered saline (PBS), the mean open circuit potential of all the coated samples were in the range of 0 to -100 mV, similar to the range seen for native Co-Cr-Mo alloy
This study has reported on the electrochemical behavior of high velocity oxygen fuel (HVOF) thermal sprayed nanocarbide cermet coatings applied to Co-Cr-Mo and Ti-6Al-4V substrates
Summary
The coated materials demonstrated higher corrosion resistance to mechanical abrasion compared to the native alloys. There are other ceramic materials such as Al2O3 and ZrO2 which have proven to be beneficial in improving the wear and corrosion performance of articulating surfaces [14,15,16,17] This excellent behavior of ceramic materials has been attributed to their better electrochemical resistance, higher abrasion resistance and better surface wettability features compared with metallic implant materials. High hardness combined with the electrochemical resistance of the carbide elements could prevent wear-related corrosion activities and enhance the load bearing capacity of native Ti-6Al-4V and Co-Cr-Mo alloys. In this study polarization testing, abrasion electrochemical testing and, EIS were applied to investigate nanocarbide coated Co-Cr-Mo and Ti-6Al-4V alloys exposed to phosphate-buffered saline and a more acidic environment to mimic aggressive crevice and/or surface inflammatory conditions.
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