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What Determines the Low-Friction Mechanism of the Silicon-Doped Diamond-like Carbon Film in a Water Environment: An Atomic-Level Understanding

Yunhai Liu, Ligao Liu, Xiaohua Zhu, Hu Zhang, Yiyao Luo, Xiaowen Wang, Penghui Xu, Bo Li

2024Langmuir8 citationsDOI

Abstract

It is widely acknowledged that doping silicon can significantly enhance the friction performance of diamond-like carbon (DLC) films in a water environment. However, the mechanism of low friction caused by doped silicon is still highly controversial. Therefore, this article compares the interface interaction between DLC and Si-DLC films in a water environment through first-principles calculations of physisorption and chemisorption effects. The results indicate that water molecules are predominantly chemically adsorbed rather than physically adsorbed on the Si-DLC surface. Further study reveals that when OH-termination is formed on the Si-DLC surface, water molecules are predominantly physically adsorbed rather than chemically adsorbed on the Si-DLC hydroxylation surface. Consequently, a more stable hydration layer is formed on the surface through the hydrogen bond network formed by Si-OH groups, ultimately leading to lower friction. Moreover, molecular dynamics simulations further suggest that the lower friction coefficient of Si-DLC films in a water environment may be due to more water molecules at the friction interface and fewer interface covalent bonds. In short, the low-friction coefficient of the Si-DLC film in a water environment may be caused not only by the chemisorption of water molecules on its surface but also by the physisorption of water molecules on the Si-DLC film after surface hydroxylation.

Topics & Concepts

SiliconDopingMechanism (biology)Diamond-like carbonCarbon fibersChemical physicsMaterials scienceDiamondAtomic force microscopyNanotechnologyChemical engineeringThin filmChemistryOptoelectronicsComposite materialPhysicsQuantum mechanicsEngineeringComposite numberDiamond and Carbon-based Materials ResearchMetal and Thin Film MechanicsForce Microscopy Techniques and Applications
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