Mechanisms of ultra-low friction by hollow inorganic fullerene-like MoS 2 nanoparticles

Abstract

Inorganic Fullerene-like (IF)-MoS 2 nanoparticles were tested under boundary lubrication and ultra-high vacuum (UHV) and were found to give an ultra-low friction coefficient in both cases compared to hexagonal (h)-MoS 2 material. Previous works made by Rapoport et al. with IF-WS 2 revealed that the benefit effect of the inorganic fullerene-like materials decreases at high loads and sliding velocities. Nevertheless, under the conditions used in our experiments using high contact pressure (maximum pressure above 1.1 GPa in oil and 400 MPa in high vacuum) and slow sliding velocities (1.7 mm/s in oil test and 1 mm/s in high vacuum), friction always decreases and stabilizes at about 0.04 for 800 cycles in both cases. Therefore, IF-MoS 2 material appears to be a good candidate for use in various environments in regard to other MoS 2 crystal structures. Wear mechanisms were investigated using both High Resolution TEM and surface analyses (XPS) on the wear tracks. Wear particles collected from the flat wear scar show several morphologies, suggesting at least two lubricating mechanisms. As spherical particles are found in the wear debris, rolling may be a possible event. However, flattened and unwrapped IF-MoS 2 particles are often observed after friction. In this case, low friction is thought to be due either to sliding between IF-MoS 2 external flattened planes or to slip between individual unwrapped MoS 2 sheets.