Frictional behavior of diamondlike carbon films in vacuum and under varying water vapor pressure

Andersson, Joakim; Erck, R.A.; Erdemir, Ali

doi:10.1016/s0257-8972(02)00617-5

Cited by 189 publications

(120 citation statements)

References 16 publications

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“…The hydrogen passivation mechanism of Erdemir [25,26] is replaced by the preferential adsorption of the most polar molecules onto the DLC surface [45], and as a consequence the friction is controlled by the molecular species at the interface as opposed to the hydrogen content of the coating. In addition, a non-hydrogenated DLC coating that shows a high coefficient of friction in an inert environment may provide a similar coefficient of friction to that of a hydrogenated coating in water [46]. Table 2 outlined the approximate range for the coefficient of friction in varying humidity and in water for a-C, a-C:H, and ta-C coatings.…”

Section: Friction In a Water Environmentmentioning

confidence: 99%

The friction of diamond-like carbon coatings in a water environment

et al. 2013

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Diamond-like carbon (DLC) coatings are known to provide beneficial mechanical and tribological properties in harsh environments. Their combination of high wear resistance and low friction has led to their extensive use in any number of industries. The tribological performance of a DLC coating is varied however, and the frictional response is known to be strongly dependent on the surrounding environment, as well as the material composition and bonding structure of the DLC coating. This paper presents an up-to-date review on the friction of DLC coatings in a water environment, with a special focus on transfer layer formation and tribochemistry.

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Section: Friction In a Water Environmentmentioning

confidence: 99%

The friction of diamond-like carbon coatings in a water environment

et al. 2013

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“…This is hypothesized to reduce friction and wear by preventing carboncarbon bonding across the sliding interface. For example, in an environment containing water or hydrogen, self-mated friction coefficients can be as low as ~0.07 for ta-C, 22 and ~0.005 for UNCD, 19 while in inert atmospheres (e.g., highly pure nitrogen or argon gas) or vacuum, the friction coefficients for both materials increase by one to two orders of magnitude. 13,19,22 Matta et al performed self-mated pin-on-disk studies with H-free amorphous carbon (a-C) and ta-C coated on ruby and sapphire substrates in an H 2 environment.…”

Section: Introductionmentioning

confidence: 99%

“…For example, in an environment containing water or hydrogen, self-mated friction coefficients can be as low as ~0.07 for ta-C, 22 and ~0.005 for UNCD, 19 while in inert atmospheres (e.g., highly pure nitrogen or argon gas) or vacuum, the friction coefficients for both materials increase by one to two orders of magnitude. 13,19,22 Matta et al performed self-mated pin-on-disk studies with H-free amorphous carbon (a-C) and ta-C coated on ruby and sapphire substrates in an H 2 environment. 12 The ta-C film in this study was grown by cathodic arc deposition, had a Young's modulus of ~650 GPa, and is mentioned to have more sp 3 -bonded carbon than the a-C films grown by sputter-ion deposition (Young's modulus ~250 GPa).…”

Section: Introductionmentioning

confidence: 99%

Influence of surface passivation on the friction and wear behavior of ultrananocrystalline diamond and tetrahedral amorphous carbon thin films

et al. 2012

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Highly sp3 -bonded, nearly hydrogen-free carbon-based materials can exhibit extremely low friction and wear in the absence of any liquid lubricant, but this physical behavior is limited by the vapor environment. The effect of water vapor on friction and wear are examined as a function of applied normal force for two such materials in thin film form -one that is fully amorphous in structure (tetrahedral amorphous carbon, or ta-C) and one that is polycrystalline with <10 nm grains (ultrananocrystalline diamond, or UNCD). Tribologically-induced changes in the chemistry and carbon bond hybridization at the surface are correlated with the effect of the sliding environment and loading conditions through ex-situ, spatially resolved near-edge x-ray absorption fine structure (NEXAFS) spectroscopy. At sufficiently high relative humidity (RH) levels and/or sufficiently low loads, both films quickly achieve a low steady-state friction coefficient and subsequently exhibit low wear. For both films, the number of cycles necessary to reach the steady-state is progressively reduced for increasing RH levels. Worn regions formed at lower RH and higher loads have a higher concentration of chemisorbed oxygen than those formed at higher RH, with the oxygen singly-bonded as hydroxyl groups (C-OH). While some carbon rehybridization from sp 3 to disordered sp 2 bonding is observed, no crystalline graphite formation is observed for either film. Rather, the primary solid-lubrication mechanism is the 2 passivation of dangling bonds by OH and H from the dissociation of vapor-phase H 2 O. This vapor-phase lubrication mechanism is highly effective, producing friction coefficients as low as 0.078 for ta-C and 0.008 for UNCD, and wear rates requiring thousands of sliding passes to produce a few nanometers of wear.

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“…Several studies have proved that the presence of hydrogen, oxygen and other environmental species in diamond-like carbon (DLC) testing environments affects the tribological behaviour of DLC wear in water [1][2][3][4][5][6][7]. The hydrogen content of DLC coatings shows low friction in inert environments due to very low adhesive forces between the fully hydrogen-terminated sliding surfaces of these carbon coatings which, as proposed by Erdemir [1,3], are not applicable when DLC slides in a water environment.…”

Section: Introductionmentioning

confidence: 99%

“…Andersson et al reported that the friction of hydrogenated DLC under varying water pressure is controlled by the water molecules that are adsorbed onto the DLC surfaces, which could change the interaction to a dipole-like one, increasing the adhesive forces and hence, the friction [5]. Studies conducted by J. Anderson et al in a high vacuum environment with various added gases also found that the presence of oxygen molecules slightly increased the friction coefficient of hydrogenated carbon films as compared to that in the hydrogen-free DLC [2], indicating the sensitivity of hydrogenated DLC to water and oxygen.…”

Section: Introductionmentioning

confidence: 99%

Depth Profile of Oxygen of Diamond-Like Carbon Sliding under Pressurized Hot Water

et al. 2017

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The wear mechanism of diamond-like carbon (DLC) in hot, pressurized water has been studied by the oxygen depth profile of DLC films pre and post a sliding test. The sliding test between DLC films coated on chromium molybdenum steel (JIS SCM420) pins and austenitic stainless steel (JIS SUS316) plates was conducted in a water environment by using high temperatures of 100, 200, 250 and 300°C and a high-pressured (10 MPa) autoclave friction tester. The dissolved oxygen concentration (DO) was 0.52 mg/L for oxygen-poor water and 40 mg/L for oxygen-rich water. The experimental results showed that the specific wear rate of DLC was strongly related to the water temperature and the DO concentration. The specific wear rate in both cases of oxygen-poor and oxygen-rich water showed a temperature dependency. When the temperature was below 200°C, the specific wear rate of DLC did not depend on the DO concentration. On the other hand, when the water temperature was more than 200°C, the specific wear rate drastically increased with the DO concentration. In order to prove the effect of oxidation on the wear rate of DLC, the depth profile of the oxygen concentration was compared to that of the carbon concentration on the inside and outside of the wear scar of DLC after sliding tests in hot, pressurized water. When the concentration of DO in the water was low at 0.52 mg/L, the O/C ratio was not affected by the water temperature. On the other hand, when the concentration of DO in water was high at 40 mg/L, the O/C ratio of the top surface increased from 0.05 to 0.18 with an increase in the water temperature on the inside of the wear scar of DLC, where the O/C ratio on the inside of the wear scar was higher than that on the outside of the scar. On the basis of the estimated rate of reaction between DLC and oxygen, determined from a linear relationship between ln (Oxidation wear volume) and the inverse temperature, it was concluded that the oxidation of DLC governed the wear of DLC in hot, pressurized water. Friction was found to enhance the oxidation wear of DLC from the estimated activation energy.

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Frictional behavior of diamondlike carbon films in vacuum and under varying water vapor pressure

Cited by 189 publications

References 16 publications

The friction of diamond-like carbon coatings in a water environment

The friction of diamond-like carbon coatings in a water environment

Influence of surface passivation on the friction and wear behavior of ultrananocrystalline diamond and tetrahedral amorphous carbon thin films

Depth Profile of Oxygen of Diamond-Like Carbon Sliding under Pressurized Hot Water

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