Effects of Oxidation on the Tribological Properties of Diamond Sliding Against Silica. Insights from Ab initio Molecular Dynamics (2304.12511v1)

Abstract: Tribological phenomena such as adhesion, friction, and wear can undermine the functionality of devices and applications based on the diamond-silica interface. Controlling these phenomena is highly desirable, but difficult since extrinsic factors, such as the surface termination by adsorbed species, can deeply affect the reactivity of diamond and its resistance to wear. In this work, we investigate the effects of diamond oxidation by massive ab initio molecular dynamics simulations of silica sliding against diamond surfaces considering different surface orientations, O-coverages, and tribological conditions. Our findings reveal a dual role of oxygen that depends on coverage. At full coverage, the adsorbed oxygen is very effective in friction and wear reduction because the repulsion with the silica counter-surface prevents the formation of chemical bonds across the interface. At reduced coverage and high pressure, Si-O-C bonds are anyway established. In this situation the presence of oxygen results detrimental as it weakens the surface C-C bonds making the surface more vulnerable to wear. Indeed we observed atomic wear on the C(110) surface at 50% O-coverage under harsh tribological conditions. The mechanisms of friction reduction and atomistic wear are explained through the analysis of the electronic properties and surface-surface interactions. Overall, our accurate in silico experiments shed light into the effects of adsorbed oxygen on the tribological behavior of diamond and show how oxidized diamond can be worn by silica.