The effects of preadsorbed CO on the chemistry of CH3 and CH3I on Pd{111}

J. J. Chen, Nicholas Winograd

Research output: Contribution to journalArticle

27 Citations (Scopus)

Abstract

The thermal decomposition of iodomethane on clean, I-precovered and CO-precovered Pd{111} is investigated using thermal desorption spectroscopy (TDS) and X-ray photoelectron spectroscopy (XPS). On a clean surface, CH3I decomposes to produce CH3,ads and Iads at temperatures between 175 and 200 K. No evidence of C2-hydrocarbon formation is observed. The CH3,ads produced by C-I bond activation hydrogenates to desorb as CH4 at 200 K. The Iads remains on the surface below 850 K and completely desorbs by 1100 K. The Iads behaves as a site blocker which removes activation sites for C-I bond activation without changing the chemical activity of CH3,ads. Compared with the results obtained from other laboratories, the thermal decomposition of CH3I on Pd is a strong structure-sensitive reaction. It was found that the C-I bond breaks at a temperature as low as 95 K on Pd{100}, whereas the C-I bond cleavage can only be observed at temperatures above 175 K on Pd{111}. The presence of CO on Pd{111} inhibits the C-I bond breaking which simultaneously influences the thermal stability of CH3,ads. Depending upon the initial coverage of CO, the hydrogenation of CH3,ads to CH4 occurs at temperatures which are up to 80 K higher than for the clean surface. The enhancement of the thermal stability of CH3,ads may result from both site blocking and electronic effects induced by preadsorbed CO.

Original languageEnglish (US)
Pages (from-to)188-200
Number of pages13
JournalSurface Science
Volume314
Issue number2
DOIs
StatePublished - Jul 20 1994

Fingerprint

Carbon Monoxide
chemistry
Chemical activation
activation
thermal decomposition
Pyrolysis
Thermodynamic stability
thermal stability
Thermal desorption spectroscopy
Temperature
temperature
Hydrocarbons
Hydrogenation
hydrogenation
cleavage
X ray photoelectron spectroscopy
hydrocarbons
desorption
photoelectron spectroscopy
augmentation

All Science Journal Classification (ASJC) codes

  • Condensed Matter Physics
  • Surfaces and Interfaces
  • Surfaces, Coatings and Films
  • Materials Chemistry

Cite this

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title = "The effects of preadsorbed CO on the chemistry of CH3 and CH3I on Pd{111}",
abstract = "The thermal decomposition of iodomethane on clean, I-precovered and CO-precovered Pd{111} is investigated using thermal desorption spectroscopy (TDS) and X-ray photoelectron spectroscopy (XPS). On a clean surface, CH3I decomposes to produce CH3,ads and Iads at temperatures between 175 and 200 K. No evidence of C2-hydrocarbon formation is observed. The CH3,ads produced by C-I bond activation hydrogenates to desorb as CH4 at 200 K. The Iads remains on the surface below 850 K and completely desorbs by 1100 K. The Iads behaves as a site blocker which removes activation sites for C-I bond activation without changing the chemical activity of CH3,ads. Compared with the results obtained from other laboratories, the thermal decomposition of CH3I on Pd is a strong structure-sensitive reaction. It was found that the C-I bond breaks at a temperature as low as 95 K on Pd{100}, whereas the C-I bond cleavage can only be observed at temperatures above 175 K on Pd{111}. The presence of CO on Pd{111} inhibits the C-I bond breaking which simultaneously influences the thermal stability of CH3,ads. Depending upon the initial coverage of CO, the hydrogenation of CH3,ads to CH4 occurs at temperatures which are up to 80 K higher than for the clean surface. The enhancement of the thermal stability of CH3,ads may result from both site blocking and electronic effects induced by preadsorbed CO.",
author = "Chen, {J. J.} and Nicholas Winograd",
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The effects of preadsorbed CO on the chemistry of CH3 and CH3I on Pd{111}. / Chen, J. J.; Winograd, Nicholas.

In: Surface Science, Vol. 314, No. 2, 20.07.1994, p. 188-200.

Research output: Contribution to journalArticle

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N2 - The thermal decomposition of iodomethane on clean, I-precovered and CO-precovered Pd{111} is investigated using thermal desorption spectroscopy (TDS) and X-ray photoelectron spectroscopy (XPS). On a clean surface, CH3I decomposes to produce CH3,ads and Iads at temperatures between 175 and 200 K. No evidence of C2-hydrocarbon formation is observed. The CH3,ads produced by C-I bond activation hydrogenates to desorb as CH4 at 200 K. The Iads remains on the surface below 850 K and completely desorbs by 1100 K. The Iads behaves as a site blocker which removes activation sites for C-I bond activation without changing the chemical activity of CH3,ads. Compared with the results obtained from other laboratories, the thermal decomposition of CH3I on Pd is a strong structure-sensitive reaction. It was found that the C-I bond breaks at a temperature as low as 95 K on Pd{100}, whereas the C-I bond cleavage can only be observed at temperatures above 175 K on Pd{111}. The presence of CO on Pd{111} inhibits the C-I bond breaking which simultaneously influences the thermal stability of CH3,ads. Depending upon the initial coverage of CO, the hydrogenation of CH3,ads to CH4 occurs at temperatures which are up to 80 K higher than for the clean surface. The enhancement of the thermal stability of CH3,ads may result from both site blocking and electronic effects induced by preadsorbed CO.

AB - The thermal decomposition of iodomethane on clean, I-precovered and CO-precovered Pd{111} is investigated using thermal desorption spectroscopy (TDS) and X-ray photoelectron spectroscopy (XPS). On a clean surface, CH3I decomposes to produce CH3,ads and Iads at temperatures between 175 and 200 K. No evidence of C2-hydrocarbon formation is observed. The CH3,ads produced by C-I bond activation hydrogenates to desorb as CH4 at 200 K. The Iads remains on the surface below 850 K and completely desorbs by 1100 K. The Iads behaves as a site blocker which removes activation sites for C-I bond activation without changing the chemical activity of CH3,ads. Compared with the results obtained from other laboratories, the thermal decomposition of CH3I on Pd is a strong structure-sensitive reaction. It was found that the C-I bond breaks at a temperature as low as 95 K on Pd{100}, whereas the C-I bond cleavage can only be observed at temperatures above 175 K on Pd{111}. The presence of CO on Pd{111} inhibits the C-I bond breaking which simultaneously influences the thermal stability of CH3,ads. Depending upon the initial coverage of CO, the hydrogenation of CH3,ads to CH4 occurs at temperatures which are up to 80 K higher than for the clean surface. The enhancement of the thermal stability of CH3,ads may result from both site blocking and electronic effects induced by preadsorbed CO.

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