Haiyang Cao scite author profile

Liquid superlubricity results in a near-frictionless lubrication state, which can greatly reduce friction and wear under aqueous conditions. However, during the running-in process, a large number of abrasive particles are generated, and because these may lead to a breakdown in superlubricity performance, they should be effectively removed. In this paper, the morphology, size, and composition of abrasive particles were verified using scanning electron microscopy with energy-dispersive X-ray spectroscopy, and their influence on liquid superlubricity was explored through friction tests. Subsequently, different solvents were used to remove the abrasive particles, and the optimal cleaning process was determined by macroscopic tribo-tests and microscopic analysis. Finally, droplet-spreading experiments and a force-curve analysis were carried out to understand the abrasive-particle removal mechanism by different solvents. We found that SiO 2 was the main component in the abrasive particles, and micron-sized SiO 2 particles resulted in random "wave peaks" in the coefficient of friction and, thus, the superlubricity. Absolute ethanol + ultrapure water was determined to be the optimal solvent for effectively removing abrasive particles from friction-pair surfaces and helped the lubricant in exhibiting an ultralow friction coefficient for long periods of time. We proposed a "wedge" and "wrap" model to explain the abrasive-particle removal mechanism of different solvents. The SiO 2 removal mechanism outlined in this study can be applied under aqueous conditions to improve the stability and durability of liquid superlubricity in practical engineering applications.

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Electrochemical effect on boundary lubrication of ZDDP additive blended in propylene carbonate / diethyl succinate

Cao

Meng

2018

Tribology International

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Microstructures and mechanical properties in B4C–CeO2 ceramics

Sun

Sakamoto

Nakai

et al. 2011

Journal of Nuclear Materials

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Haiyang Cao

Geochemical characteristics of the lower Silurian Longmaxi Formation on the Yangtze Platform, South China: Implications for depositional environment and accumulation of organic matters

Effects of Abrasive Particles on Liquid Superlubricity and Mechanisms for Their Removal

Electrochemical effect on boundary lubrication of ZDDP additive blended in propylene carbonate / diethyl succinate

Microstructures and mechanical properties in B4C–CeO2 ceramics

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