Key Role of Transfer Layer in Load Dependence of Friction on Hydrogenated Diamond-Like Carbon Films in Humid Air and Vacuum

The friction of hydrogenated diamond-like carbon (H-DLC) films was evaluated under the controlled environments of humid air and vacuum by varying the applied load. In humid air, there is a threshold applied load below which no obvious friction drop occurs and above which the friction decreases to a...

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Published in:Materials 2019-05, Vol.12 (9), p.1550
Main Authors: Liu, Yunhai, Chen, Lei, Zhang, Bin, Cao, Zhongyue, Shi, Pengfei, Peng, Yong, Zhou, Ningning, Zhang, Junyan, Qian, Linmao
Format: Article
Language:English
Subjects:
Diamond films
Diamond-like carbon films
Friction
Graphitization
Humidity
Hydrogen
Hydrogenation
Load
Low level
Silicon wafers
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cited_by cdi_FETCH-LOGICAL-c472t-9c98fcc1ba6d2083cf791bde2b61548a2e4d700f2ba2d8ccc40465223002c3513
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container_issue 9
container_start_page 1550
container_title Materials
container_volume 12
creator Liu, Yunhai
Chen, Lei
Zhang, Bin
Cao, Zhongyue
Shi, Pengfei
Peng, Yong
Zhou, Ningning
Zhang, Junyan
Qian, Linmao
description The friction of hydrogenated diamond-like carbon (H-DLC) films was evaluated under the controlled environments of humid air and vacuum by varying the applied load. In humid air, there is a threshold applied load below which no obvious friction drop occurs and above which the friction decreases to a relatively low level following the running-in process. By contrast, superlubricity can be realized at low applied loads but easily fails at high applied loads under vacuum conditions. Further analysis indicates that the graphitization of the sliding H-DLC surface has a negligible contribution to the sharp drop of friction during the running-in process under both humid air and vacuum conditions. The low friction in humid air and the superlow friction in vacuum are mainly attributed to the formation and stability of the transfer layer on the counterface, which depend on the load and surrounding environment. These results can help us understand the low-friction mechanism of H-DLC film and define optimized working conditions in practical applications, in which the transfer layer can be maintained for a long time under low applied load conditions in vacuum, whereas a high load can benefit the formation of the transfer layer in humid air.
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subjects Diamond films
Diamond-like carbon films
Friction
Graphitization
Humidity
Hydrogen
Hydrogenation
Load
Low level
Silicon wafers
title Key Role of Transfer Layer in Load Dependence of Friction on Hydrogenated Diamond-Like Carbon Films in Humid Air and Vacuum
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