Abstract
To improve the thermal stability and mechanical performances of the DLC coating at high temperature, thermodynamically stable Si-N and C-N bonds were introduced into the DLC coating by co-doping Si and N elements. The friction coefficient and wear rate changed from 0.055 and 1.93 x 10(-7) mm(3)/Nm (25 degrees C) to 0.033 and 7.3 x 10(-6) mm(3)/Nm (500 degrees C). The superior tribological performances of Si, N-DLC coating at 500 degrees C was attributed to the formation of compacted layers with high hardness (9.2 GPa) and elastic recovery (similar to 89%) on the wear track during running-in period. The compacted layer possessed a high compliance and large deformation capacity due to the fullerene-like nanostructure within amorphous carbon network and the shear-induced stacked structure, thereby reducing the friction.

Keywords Plus：AMORPHOUS-CARBONLOW-FRICTIONFILMSMICROSTRUCTUREPERFORMANCEGRAPHENEORIGIN

Published in TRIBOLOGY INTERNATIONAL，Volume175；10.1016/j.triboint.2022.107845，NOV 2022