Effect of coadsorbed water on deep oxidation mechanisms: temperature-programmed reactions of benzene and hydroxyl on the pt(111) surface

The deep oxidation of benzene by preadsorbed hydroxyl on the Pt(111) surface has been characterized using temperature-programmed reaction spectroscopy. A mechanism for benzene oxidation in the presence of coadsorbed water has been developed based on these experiments. Reaction-limited carbon dioxide...

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Bibliographic Details
Published inCatalysis letters Vol. 93; no. 3-4; pp. 165 - 170
Main Authors MARSH, Anderson L, GLAND, John L
Format Journal Article
LanguageEnglish
Published Dordrecht Springer 01.03.2004
Springer Nature B.V
Subjects
Atomic oxygen
Benzene
Carbon dioxide
Catalysis
Chemistry
Dehydrogenation
Exact sciences and technology
General and physical chemistry
Hydrocarbons
Oxidation
Temperature
Theory of reactions, general kinetics. Catalysis. Nomenclature, chemical documentation, computer chemistry
Water
Catalytic reaction
Surface reaction
Hydrocarbon
Desorption
Single crystal
Surface
Programmed temperature
Chemical reaction
Platinum
Benzene
Reaction mechanism
Oxidation
Catalysis
Hydroxyl
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Summary:The deep oxidation of benzene by preadsorbed hydroxyl on the Pt(111) surface has been characterized using temperature-programmed reaction spectroscopy. A mechanism for benzene oxidation in the presence of coadsorbed water has been developed based on these experiments. Reaction-limited carbon dioxide and water are formed over the temperature range 330–530 K, indicating oxydehydrogenation and skeletal oxidation are occurring over this temperature range. Oxidation of benzene has been compared on the oxygen-covered Pt(111) surface with and without coadsorbed water. With preadsorbed hydroxyl, the yield of water at low-temperatures is increased, and the yield of carbon dioxide is increased. The temperature ranges for carbon dioxide and water formation above 300 K are increased by 30 K when water is coadsorbed with atomic oxygen to form hydroxyl. These results clearly suggest that hydroxyl enhances oxydehydrogenation below 300 K, which results in the formation of different dehydrogenated intermediates with increased activation energy for oxidation during the reaction. Taken together these kinetic and mechanistic results provide a clear description of the reactivity of hydroxyl during benzene deep oxidation on the Pt(111) surface.
ISSN:1011-372X
1572-879X
DOI:10.1023/B:CATL.0000017071.15340.46