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Tribochemical Lubricious Oxides on Silicon Nitride

Published online by Cambridge University Press:  28 February 2011

T. E. Fischer ,
H. Liang  and
W. M. Mullins
T. E. Fischer
Affiliation:
Stevens Institute of Technology, Hoboken, NJ 07008
H. Liang
Affiliation:
Stevens Institute of Technology, Hoboken, NJ 07008
W. M. Mullins
Affiliation:
Stevens Institute of Technology, Hoboken, NJ 07008
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Abstract

The concept of lubrication by a tribochemically generated oxide layer on the surface of silicon nitride is further investigated. Previous work has shown that low friction coefficients (μ≈0.1) are obtained in a range of sliding velocities and loads when otherwise unlubricated silicon nitride slides in humid air at temperatures between 150 and 650ºC. In order to verify the hypothesis that this behavior results from a competition between the growth of an oxide layer (with growth kinetics accelerated by friction) and its removal by wear, we have performed model experiments at room temperature, wherethe oxide layer is grown statically (i.e. without friction) and the friction coefficient and its evolution in time are subsequently measured. In order to avoid high friction by plowing, ultraflat surfaces were first prepared by sliding in water. The experiments showed that the oxide layer growing in humid air on silicon nitride produces a friction coefficient as low as μ≈0.05 that survives about 30 Newton meter of sliding, which corresponds to several hundred passes of the counterface. When sliding in water, the surface acquires a high friction coefficient (μ≈0.7) very rapidly. The difference in the lubricating properties of tribochemical surface layers on aluminum oxide and silicon nitride can be understood on the basis of the differing surface chemistries of these materials. We offer a tentative lubrication mechanism based on low adhesion between the oxide surface and the silicon nitride counterface and the structure of oxides grown inhumid ambients.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 140: Symposium S – New Materials Approaches to Tribology: Theory and Applications , 1988 , 339
Copyright
Copyright © Materials Research Society 1989

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References

1. Klaus, E.E. and Lai, C.W., in “Solid and Liquid Lubricants for extreme environmentsASLE Spec. Publ. 15 75 (1982)Google Scholar
2. Tomizawa, H. and Fischer, T.E., ASLE Trans. 29 481 (1986)Google Scholar
3. Fischer, T.E. and Tomizawa, H., Wear 105 29 (1985)Google Scholar
4. Fischer, T.E., Ann. Rev. Mater. Sci. 18 303 (1988)Google Scholar
5. Komvopoulos, K., Saka, N. and Suh, N. P., J. Tribology (ASME Trans.) 107 452 (1985) and ibid. 108 301 (1986)Google Scholar
6. Tomizawa, H. and Fischer, T.E., ASLE Trans. 30 41 (1987)Google Scholar
7. Sugita, T., Ueda, K. and Kanemura, Y., Wear 97 1 (1984)Google Scholar
8. Fehlner, F.P., “Low-Temperature Oxidation, The Role of Vitreous OxidesJohn Wiley and Sons, New York, (1986), p.180 Google Scholar
9. Jahanmir, S. and Fischer, T.E., Tribology Trans. 31 32 (1988)Google Scholar
10. Gates, R., Hsu, S.M. and Klaus, E.E., STLE Trans. in press (preprint STLE 88-TC-5A-4)Google Scholar
11. Wefers, K. and Bell, G., “Oxides and Hydroxides of Aluminum” Technical Paper No. 19, Alcoa Research Laboratories, (1972)Google Scholar
12. Iler, R.K., “The Chemistry of Silica”, John Wiley and Sons, New York (1979), p. 622 Google Scholar
13. Dalal, H.M., Chiu, Y.P. and Rabinowicz, E., ASLE Trans. 18 211 (1975)Google Scholar