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On Microfaceting Instability of Pt(110) Under Catalytic Oxidation of Adsorbed Co

Published online by Cambridge University Press:  25 February 2011

M. Papoular*
Affiliation:
Centre de Recherches sur les Très Basses Tempèratures, CNRS, BP 166, 38042Grenoble Cèdex 09
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Abstract

As demonstrated by recent STM [1] and LEED [2] experiments the platinum (110) surface undergoes, at carbon monoxide submonolayer coverages, a phase transition from the 1 x 2 “missing-row” (reconstructed) state to the 1 x 1(bulk-like) state under specific temperature and partial-pressure conditions. The catalytic oxidation reaction CO + 1/2 → CO2 drives a microfaceting instability [3] [4] of the Pt(110) surface which ends up in a regular sawtooth profile with a period ≈ 200 Å, along the [110] direction.

We introduce the idea that the rather extensive Pt mass transport, as involved in the process, could be energetically assisted by the reaction itself. Energy and momentum-balance considerations lead us to expect an energy ≲ 0.5 eV to be transferrable to thesubstrate. This should efficiently contribute to initiating the “scraping”process that leads to the microfaceted pattern.

A simple model for nucleation and growth of facets is presented (see ref. 5), yielding characteristic times of order minutes (at T = 500 K), in fair agreement with experiment.

Independently of the structural/catalytic problem, adsorption of CO at submonolayer coverages on, e.g., Pt(110) might be of interest from a surfactantphysics point of view (see ref. 6 for a very recent study on layer-by-layer homoepitaxial metal growth).

Type
Research Article
Copyright
Copyright © Materials Research Society 1992

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References

REFERENCES

1 GRITISCH, T., COULMAN, D., BEHM, R.J., ERTL, G., Phys. Rev. Lett. 63, 1086 (1989).Google Scholar
2 MATSUSHIMA, T., J. Chem. Phys. 93, 1464 (1990).Google Scholar
3 FALTA, J., IMBIHL, R., HENZLER, M., Phys. Rev. Lett. 64, 1409 (1990).Google Scholar
4 IMBIHL, R., REYNOLDS, A.E., KALETTA, D., Phys. Rev. Lett. 67, 275 (1991).Google Scholar
5 PAPOULAR, M., J. Phys. II, Fr. 2, 987 (1992).Google Scholar
6 VEGT, H.A. VAN DER, PINXTEREN, H.M. VAN, LOHMEIER, M., VLIEG, E. and THORNTON, J.M., Phys. Rev. Lett. 68, 3335 (1992).Google Scholar