Catalytic hydroxylation of benzene and cyclohexane using in situ generated hydrogen peroxide: new mechanistic insights and comparison with hydrogen peroxide added directly

Catalytic hydroxylation of benzene and cyclohexane using in situ generated hydrogen peroxide: new mechanistic insights and comparison with hydrogen peroxide added directly

Hydrogen peroxide is considered an ideal “green” oxidant due to its high oxidizing ability and lack of toxic by-products. Herein, we report on an oxidation procedure that couples metallic palladium-catalyzed in situ hydrogen peroxide generation from dihydrogen and dioxygen with a second vanadium or...

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Bibliographic Details
Published in:Journal of molecular catalysis. A, Chemical Vol. 203; no. 1; pp. 179 - 192
Main Authors: Remias, Joseph E., Pavlosky, Thomas A., Sen, Ayusman
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 01-09-2003
Elsevier
Subjects:
Benzene
Catalysis
Catalytic hydroxylation
Catalytic reactions
Chemistry
Cyclohexane
Cyclohexanol
Exact sciences and technology
General and physical chemistry
Hydrogen peroxide
Iron
Palladium
Phenol
Theory of reactions, general kinetics. Catalysis. Nomenclature, chemical documentation, computer chemistry
Vanadium
Phenol
Hydrogen peroxide
Benzene
Vanadium
Cyclohexane
Palladium
Iron
Cyclohexanol
Catalytic hydroxylation
Catalytic reaction
Vanadium complex
Hydrocarbon
Hydroxylation
Benzoquinone
Transition metal Complexes
Cycloalkane
Hydrogen Peroxides
Supported catalyst
Oxo complex
Heterogeneous catalysis
Aluminium Oxides
Acetylacetone
Iron complex
Platinoid
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Summary:Hydrogen peroxide is considered an ideal “green” oxidant due to its high oxidizing ability and lack of toxic by-products. Herein, we report on an oxidation procedure that couples metallic palladium-catalyzed in situ hydrogen peroxide generation from dihydrogen and dioxygen with a second vanadium or iron catalyst that utilizes the hydrogen peroxide for the hydroxylation of benzene and cyclohexane. Studies indicate that the slow step in the overall reaction is the formation of usable hydrogen peroxide, and the mechanism of hydroxylation by the second catalyst is not affected by the presence of metallic palladium. The reported procedure, which resembles monoxygenases, allows the direct use of dioxygen in catalytic oxidations. Comparisons between the in situ method of hydrogen peroxide generation and hydrogen peroxide added via syringe pump show that the in situ method is more selective. Additionally, new insight into the mechanism of vanadium-catalyzed benzene hydroxylation is reported. Mechanistic investigations include the observation of a high NIH shift, the use of a radical cation rearrangement probe, and the first use of H 2 18 O enrichment studies. Based on these, an electron transfer mechanism resulting in a radical cation intermediate is proposed.
ISSN:1381-1169
1873-314X
DOI:10.1016/S1381-1169(03)00212-7