Spin Trapping of Au-H Intermediate in the Alcohol Oxidation by Supported and Unsupported Gold Catalysts

TY - JOUR

T1 - Spin Trapping of Au-H Intermediate in the Alcohol Oxidation by Supported and Unsupported Gold Catalysts

AU - Conte, Marco

AU - Miyamura, Hiroyuki

AU - Kobayashi, Shu

AU - Chechik, Victor

PY - 2009/5/27

Y1 - 2009/5/27

N2 - Electron paramagnetic resonance (EPR) spectroscopy and spin trapping were used to explore the mechanism of alcohol oxidation over gold catalysts. Reaction of secondary alcohols with supported and unsupported gold catalysts (e.g., Au/CeO2, polymer-incarcerated Au nanoparticles, PPh3-protected Au nanoparticles) in the presence of spin traps led to the formation of a hydrogen spin adduct. Using isotope labeling, we confirmed that the hydrogen in the spin adduct originates from the cleavage of the C-H bond in the alcohol molecule. The formation of the hydrogen spin adduct most likely results from the abstracting of hydrogen from the Au surface by a spin trap. These results thus strongly suggest intermediate formation Au-H species during alcohol. This was further confirmed by carrying out gold-catalyzed alcohol oxidation in the absence of oxygen, with nitroxides as hydrogen abstractors. The support (e.g., metal oxides) can activate oxygen and act as an H abstractor from the gold surface and hence lead to a faster recovery of the activity. Peroxyl radicals were also observed during alcohol oxidation, consistent with a free-radical autoxidation mechanism. However, this mechanism is likely to be a minor side reaction, which does not lead to the formation of an appreciable amount of oxidation products.

AB - Electron paramagnetic resonance (EPR) spectroscopy and spin trapping were used to explore the mechanism of alcohol oxidation over gold catalysts. Reaction of secondary alcohols with supported and unsupported gold catalysts (e.g., Au/CeO2, polymer-incarcerated Au nanoparticles, PPh3-protected Au nanoparticles) in the presence of spin traps led to the formation of a hydrogen spin adduct. Using isotope labeling, we confirmed that the hydrogen in the spin adduct originates from the cleavage of the C-H bond in the alcohol molecule. The formation of the hydrogen spin adduct most likely results from the abstracting of hydrogen from the Au surface by a spin trap. These results thus strongly suggest intermediate formation Au-H species during alcohol. This was further confirmed by carrying out gold-catalyzed alcohol oxidation in the absence of oxygen, with nitroxides as hydrogen abstractors. The support (e.g., metal oxides) can activate oxygen and act as an H abstractor from the gold surface and hence lead to a faster recovery of the activity. Peroxyl radicals were also observed during alcohol oxidation, consistent with a free-radical autoxidation mechanism. However, this mechanism is likely to be a minor side reaction, which does not lead to the formation of an appreciable amount of oxidation products.

KW - POLYMER-INCARCERATED PALLADIUM

KW - SELECTIVE AEROBIC OXIDATION

KW - LIQUID-PHASE OXIDATION

KW - RUTHENIUM CATALYSTS

KW - MOLECULAR-OXYGEN

KW - ACTIVE CATALYST

KW - FREE-RADICALS

KW - PD CATALYST

KW - HYDROGENATION

KW - NANOPARTICLES

UR - http://www.scopus.com/inward/record.url?scp=70349144552&partnerID=8YFLogxK

U2 - 10.1021/ja809883c

DO - 10.1021/ja809883c

M3 - Article

SN - 0002-7863

VL - 131

SP - 7189

EP - 7196

JO - Journal of the American Chemical Society

JF - Journal of the American Chemical Society

IS - 20

ER -