Formation of wear-resistant graphite/diamond-like carbon nanocomposite coatings on Ti using accelerated C60-ions

The nanostructural and tribological characteristics of carbon nanocomposite coatings (CNCs), deposited by accelerated C-60 ions at high temperatures, were studied. The CNCs were successfully fabricated on Ti-alloy using a flux that contained C-60 ions with 5 and 10 keV energies. Unlike the previous studies, ion mass-separator was not implemented to the deposition process. This enabled deposition of sp(2)-rich CNCs with a lower coefficient of friction (COF) at a higher deposition rate. Laser confocal microscopy, atomic force microscopy transmission electron microscopy, Raman spectroscopy, X-ray photoelectron spectroscopy, and X-ray Auger Electron Spectroscopy were used to investigate the structure of the coatings and friction test results. A carbon nanocomposite film consisting of graphite nanocrystals enclosed in an amorphous diamond-like matrix was formed at a deposition temperature of 300-400 degrees C. Upon deposition of the CNC, a COF of similar to 0.06 was achieved, which was almost one order of magnitude lower than that of bare Ti-alloy substrate. The surface wear was reduced by 360 times. The wear mechanism was changed from abrasive wear (on bare Ti-alloy) to a burnishing smoothening of the surface roughness (on CNCs). The transfer of graphite nanocrystals from the coating to the counter surface was identified and observed to act as a solid lubricant.

Automated summary

Carbon nanocomposite coatings (CNCs), fabricated by accelerated C-60 ions at high temperatures, showed reduced coefficient of friction (COF) and surface wear, with graphite nanocrystals enclosed in a diamond-like matrix. The wear mechanism shifted from abrasive wear to burnishing smoothening due to the transfer of graphite nanocrystals acting as a solid lubricant.