Unraveling the friction response from selective hydrogenation of textured amorphous carbon surface

Authors
Du, NaizhouWei, XubingLi, XiaoweiChen, ZanLu, ShiqiDing, JiaqingFeng, CunaoChen, KaiQiao, JianghaoZhang, DekunLee, Kwang-Ryeol
Issue Date
2023-03
Publisher
Elsevier BV
Citation
Applied Surface Science, v.614
Abstract
Ultra-low friction of amorphous carbon (a-C) film can be achieved by binding to hydrogen atoms or texturing conformations. However, it remains unclear how selective surface hydrogenation affects the friction behavior of textured a-C film. In particular, the corresponding transformation of interfacial structure and the movement of hydrogen atoms have not yet been reported because of the limitation of in-situ experimental characterization. Here, textured a-C films with selective hydrogenated surfaces were prepared, and the corresponding friction response and the transformation of interfacial structure were investigated systematically using reactive molec-ular dynamics simulation. Results showed that introducing hydrogen atoms to the selective bump sites of textured a-C surfaces significantly reduced the friction coefficient; however, its efficiency was closely sensitive to the hydrogen content, which was related to the interfacial passivation and the repulsion effect induced by H atoms. Most importantly, the separation of -CH clusters from textured a-C surface during sliding process and their re-bonding with the naked mating a-C surface played a key role in further enhancing the repulsive effect between contacted a-C surfaces, thereby improving the anti-friction behavior, which has not been mentioned in previous studies. These results suggest a new approach to develop the high-efficient a-C friction system for applications.
Keywords
DIAMOND-LIKE CARBON; MOLECULAR-DYNAMICS; FILMS; DEPENDENCE; INSIGHTS; MECHANISM; Amorphous carbon; Hydrogenation; Textured surface; Friction mechanism; Reactive molecular dynamics
ISSN
0169-4332
URI
https://pubs.kist.re.kr/handle/201004/113968
DOI
10.1016/j.apsusc.2022.156246
Appears in Collections:
KIST Article > 2023
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