具有分级表面结构的DLC膜在水润滑下的摩擦学行为:分子动力学模拟

Huang-Chuan Chen, Guangan Zhang, Zhibin Lu, Xia Li, N. Srikanth, Lichun Bai
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引用次数: 4

摘要

通过分子动力学模拟研究了具有不同层次表面结构的类金刚石(DLC)膜与润滑剂水分子的摩擦学行为。在小法向载荷下,由于水分子在DLC膜之间的完全分离,摩擦力稳定在一个较小的值,而在大法向载荷下,摩擦力在界面演化和水行为的共同作用下表现出复杂的变化。在大的法向载荷下,摩擦力首先由于表面织构的直接接触而增加,而表面织构随后被磨损和石墨化,导致摩擦力暂时稳定在一个大值。随着界面碳团簇的进一步磨损,界面碳团簇数量减少,水分子在界面处分布均匀,摩擦力逐渐减小,最终趋于稳定。在滑动过程中,水分子在氢键结构和数量上的恢复,使得这些分子在不同的阶段发挥不同的作用,即在摩擦上升过程中,这些分子表现出更好的扩散,在摩擦稳定过程中,这些分子对DLC膜的分离作用增强。同样数量的水分子在一级层次(L1)模型中比在二级层次(L2)模型中具有更大的承载能力。当法向载荷超过水的承载能力时,磨合期后,由于界面平坦,水分子分布均匀,L2模型的摩擦力比L1模型更稳定、更小。
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Tribological behaviors of DLC films with hierarchical surface textures under water lubrication: A molecular dynamic simulation
Tribological behaviors of diamond-like carbon (DLC) films with different levels of hierarchical surface textures with lubricant water molecules are investigated through molecular dynamics simulation. The friction forces stabilize at a small value for small normal loads, due to the complete separation between DLC films by water molecules, while friction forces with large normal loads show complicated changes under the cooperation of interfacial evolution and water behaviors. Under large normal loads, friction force increases firstly due to the direct contact of surface textures which are subsequently worn and graphitized, resulting in the temporary stabilization of friction force at a large value. With their further wearing, the amount of interfacial carbon clusters decreases and water molecules distribute evenly at interface, which leads to the gradual decrease and final stabilization of friction force. During the sliding, the water molecules show a restoration in the structure and amount of hydrogen bonds, thus making these molecules play different roles in various stages, i.e., these molecules demonstrate a better diffusion during the friction rise and an enhanced separating effect for DLC films during the friction stabilization. Furthermore, the same amount of water molecules in the one-level hierarchical (L1) model has a larger bearing capacity than that in the two-level hierarchical (L2) model. When the normal load exceeds the bearing capacity of water, the friction force for model L2 is more stable and smaller than that for model L1 after running-in periods due to flattened interfaces and evenly distributed water molecules.
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来源期刊
Journal of Micromechanics and Molecular Physics
Journal of Micromechanics and Molecular Physics Materials Science-Polymers and Plastics
CiteScore
3.30
自引率
0.00%
发文量
27
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