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Pyrolytic Carbon Deposition on Graphitic Surfaces

Published online by Cambridge University Press:  15 February 2011

Ismail M. K. Ismail*
Affiliation:
University of Dayton Research Institute c/o Phillips Laboratory/RKFC, Edwards Air Force Base, CA 93523-5000, USA
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Abstract

The present study outlines the importance of carbon active sites in controlling the kinetics of pyrolytic carbon deposition on a graphitized pitch fiber at 1025°C. Blockage of active sites with chemisorbed hydrogen retards deposition rates substantially. Removal of the chemisorbed hydrogen from the occupied sites raises deposition rates to the normal values noted on a fresh “clean” surface. The effect of surface activation prior to deposition is discussed. Activating the surface generates additional active sites and enhances the rates. However, not all the newly developed sites contribute to the kinetics. After the deposition of the first carbon layer, a fraction of those newly developed sites is instantaneously blocked and does not further contribute to subsequent deposition. The remaining fraction, along with the original sites available before activation, keeps replicating during the remaining course of deposition. That is, the disappearance of one active site after carbon deposition is associated with the generation of a new site. This trend continues up to the deposition of 60 carbon layers.

Type
Research Article
Copyright
Copyright © Materials Research Society 1992

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