Probing the friction mechanism of diamond-like carbon films in aqueous environments based on molecular dynamics simulations

XH Zhu and XW Wang and YH Liu and YY Luo and H Zhang and B Li and X Zhao, MODELLING AND SIMULATION IN MATERIALS SCIENCE AND ENGINEERING, 32, 085019 (2024).

DOI: 10.1088/1361-651X/ad8ad6

The frictional behavior of diamond-like carbon (DLC) films in an aqueous environment is of tremendous interest. To compare the impacts of the quantity of water molecules, sliding velocity, and loading on the friction behavior of DLC films, a molecular model of DLC films in an aqueous environment was built. The results show that the DLC film under high load and high sliding velocity leads to severe friction behavior, but the water molecules can prevent the occurrence of this severe friction behavior. Also increasing the number of water molecules can effectively reduce the increase in friction during the running-in stage and keep it at a low value. The primary explanation is that if there are enough water molecules, they will create a stable water film at the friction interface and prevent large-scale contact and distortion between the upper and lower DLC films, significantly reducing friction.

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