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The Oxidation Behavior of the √3×√3 Ag and Au/Si(111) Surfaces at Room Temperature Studied by Photoemission

Published online by Cambridge University Press:  26 February 2011

J. J. Yeh ,
D. J. Friedman ,
R. Cao ,
J. Hwang ,
J. Nogami  and
I. Lindau
J. J. Yeh
Affiliation:
Stanford Electronica Laboratories, Stanford, CA 94305.
D. J. Friedman
Affiliation:
Stanford Electronica Laboratories, Stanford, CA 94305.
R. Cao
Affiliation:
Stanford Electronica Laboratories, Stanford, CA 94305.
J. Hwang
Affiliation:
Stanford Electronica Laboratories, Stanford, CA 94305.
J. Nogami
Affiliation:
Stanford Electronica Laboratories, Stanford, CA 94305.
I. Lindau
Affiliation:
Stanford Electronica Laboratories, Stanford, CA 94305.
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Abstract

The differences of the room temperature oxidation behavior of ordered Ag/Si(111) and Au/Si(111) surfaces were studied by surface sensitive soft x-ray photoemission spectroscopy obtained with synchrotron radiation. Si surfaces covered with a monolayer of Ag or Au, once annealed to display a √3×√3 LEED pattern, were believed to be passivated against oxidation according to earlier reports. This work shows that these two surfaces oxidize but in a different way. Up to 104 L O2 exposures, the observed valence band of the Au/Si surface's valence band electron energy distribution curve is almost identical to that of the surface before oxygen exposure. But the corresponding Si 2p core level spectrum shows a small chemically shifted component indicating an initial stage of the formation of Si oxide. Thi3 chemically shifted signal becomes a strong peak at -3.7 eV below the clean Si position, characteristic of SiO2, after subsequent O2 exposures up to 1010 L. The Ag/Si system behaves in a similar fashion, but oxide growth saturates at 108 L, and the final oxides formed include a distribution of suboxides in addition to SiO2. Clearly, oxide formation is not prohibited by the presence of the ordered Au or Ag metal overlayer but delayed. Although the onset of oxidation is delayed compared to that for the clean Si surface, due to the metal-silicon bonding, the oxide formation is much faster once the surface starts to oxidize.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 54: Symposium E – Thin Films–Interfaces and Phenomena , 1985 , 605
Copyright
Copyright © Materials Research Society 1986

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References

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