Multiple CO Oxidation Promoted by Au2Dimers in Au2TiO4−Cluster Anions

Xiao Na Li; Zi Yu Li; Hai Fang Li; Sheng Gui He

doi:10.1002/chem.201600451

Multiple CO Oxidation Promoted by Au₂Dimers in Au₂TiO₄⁻Cluster Anions

Xiao Na Li, Zi Yu Li, Hai Fang Li, Sheng Gui He^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

20 Citations (Scopus)

Abstract

Time-of-flight mass spectrometry experiments demonstrated that laser ablation generated and mass selected Au₂TiO₄⁻cluster anions can unexpectedly oxidize three CO molecules in an ion trap reactor. This is an improvement on the more commonly observed oxidation of at most two CO molecules by a doped cluster. Quantum chemistry calculations were performed to rationalize the reactions. The lowest energy isomer of Au₂TiO₄⁻contains a superoxide unit, the participation of which in CO oxidation can be promoted by the Au₂dimer. The Au₂dimer functions as a rather flexible electron reservoir in each CO oxidation step in terms of the release and storage of electrons to drive the dissociation of superoxide to peroxide and then to lattice oxygen atoms, which can be removed by reaction with CO molecules. This gas-phase study enriches our understanding toward the nature of reactive oxygen species involved in gold-catalyzed oxidation reactions.

Original language	English
Pages (from-to)	9024-9029
Number of pages	6
Journal	Chemistry - A European Journal
Volume	22
Issue number	26
DOIs	https://doi.org/10.1002/chem.201600451
Publication status	Published - 20 Jun 2016
Externally published	Yes

Keywords

CO oxidation
clusters
density functional calculations
gold dimers
mass spectrometry

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10.1002/chem.201600451

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title = "Multiple CO Oxidation Promoted by Au2Dimers in Au2TiO4−Cluster Anions",

abstract = "Time-of-flight mass spectrometry experiments demonstrated that laser ablation generated and mass selected Au2TiO4−cluster anions can unexpectedly oxidize three CO molecules in an ion trap reactor. This is an improvement on the more commonly observed oxidation of at most two CO molecules by a doped cluster. Quantum chemistry calculations were performed to rationalize the reactions. The lowest energy isomer of Au2TiO4−contains a superoxide unit, the participation of which in CO oxidation can be promoted by the Au2dimer. The Au2dimer functions as a rather flexible electron reservoir in each CO oxidation step in terms of the release and storage of electrons to drive the dissociation of superoxide to peroxide and then to lattice oxygen atoms, which can be removed by reaction with CO molecules. This gas-phase study enriches our understanding toward the nature of reactive oxygen species involved in gold-catalyzed oxidation reactions.",

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author = "Li, {Xiao Na} and Li, {Zi Yu} and Li, {Hai Fang} and He, {Sheng Gui}",

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doi = "10.1002/chem.201600451",

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AU - Li, Xiao Na

AU - Li, Zi Yu

AU - Li, Hai Fang

AU - He, Sheng Gui

PY - 2016/6/20

Y1 - 2016/6/20

N2 - Time-of-flight mass spectrometry experiments demonstrated that laser ablation generated and mass selected Au2TiO4−cluster anions can unexpectedly oxidize three CO molecules in an ion trap reactor. This is an improvement on the more commonly observed oxidation of at most two CO molecules by a doped cluster. Quantum chemistry calculations were performed to rationalize the reactions. The lowest energy isomer of Au2TiO4−contains a superoxide unit, the participation of which in CO oxidation can be promoted by the Au2dimer. The Au2dimer functions as a rather flexible electron reservoir in each CO oxidation step in terms of the release and storage of electrons to drive the dissociation of superoxide to peroxide and then to lattice oxygen atoms, which can be removed by reaction with CO molecules. This gas-phase study enriches our understanding toward the nature of reactive oxygen species involved in gold-catalyzed oxidation reactions.

AB - Time-of-flight mass spectrometry experiments demonstrated that laser ablation generated and mass selected Au2TiO4−cluster anions can unexpectedly oxidize three CO molecules in an ion trap reactor. This is an improvement on the more commonly observed oxidation of at most two CO molecules by a doped cluster. Quantum chemistry calculations were performed to rationalize the reactions. The lowest energy isomer of Au2TiO4−contains a superoxide unit, the participation of which in CO oxidation can be promoted by the Au2dimer. The Au2dimer functions as a rather flexible electron reservoir in each CO oxidation step in terms of the release and storage of electrons to drive the dissociation of superoxide to peroxide and then to lattice oxygen atoms, which can be removed by reaction with CO molecules. This gas-phase study enriches our understanding toward the nature of reactive oxygen species involved in gold-catalyzed oxidation reactions.

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KW - density functional calculations

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KW - mass spectrometry

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Multiple CO Oxidation Promoted by Au₂Dimers in Au₂TiO₄⁻Cluster Anions

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Keywords

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