The Active Phase of Palladium during Methane Oxidation

A. Hellman; A. Resta; Natalia Martin; Johan Gustafson; A. Trinchero; P. -A. Carlsson; O. Balmes; R. Felici; R. van Rijn; J. W. M. Frenken; Jesper N Andersen; Edvin Lundgren; H. Gronbeck

doi:10.1021/jz300069s

The Active Phase of Palladium during Methane Oxidation

A. Hellman, A. Resta, Natalia Martin, Johan Gustafson, A. Trinchero, P. -A. Carlsson, O. Balmes, R. Felici, R. van Rijn, J. W. M. Frenken, Jesper N Andersen, Edvin Lundgren, H. Gronbeck

Synchrotron Radiation Research

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

Abstract

The active phase of Pd during methane oxidation is a long-standing puzzle, which, if solved, could provide routes for design of improved catalysts. Here, density functional theory and in situ surface X-ray diffraction are used to identify and characterize atomic sites yielding high methane conversion. Calculations are performed for methane dissociation over a range of Pd and PdOx surfaces and reveal facile dissociation on either under-coordinated Pd sites in PdO(101) or metallic surfaces. The experiments show unambiguously that high methane conversion requires sufficiently thick PdO(101) films or metallic Pd, in full agreement with the calculations. The established link between high activity and atomic structure enables rational design of improved catalysts.

Original language	English
Pages (from-to)	678-682
Journal	The Journal of Physical Chemistry Letters
Volume	3
Issue number	6
DOIs	https://doi.org/10.1021/jz300069s
Publication status	Published - 2012

Subject classification (UKÄ)

Atom and Molecular Physics and Optics

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10.1021/jz300069s

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title = "The Active Phase of Palladium during Methane Oxidation",

abstract = "The active phase of Pd during methane oxidation is a long-standing puzzle, which, if solved, could provide routes for design of improved catalysts. Here, density functional theory and in situ surface X-ray diffraction are used to identify and characterize atomic sites yielding high methane conversion. Calculations are performed for methane dissociation over a range of Pd and PdOx surfaces and reveal facile dissociation on either under-coordinated Pd sites in PdO(101) or metallic surfaces. The experiments show unambiguously that high methane conversion requires sufficiently thick PdO(101) films or metallic Pd, in full agreement with the calculations. The established link between high activity and atomic structure enables rational design of improved catalysts.",

author = "A. Hellman and A. Resta and Natalia Martin and Johan Gustafson and A. Trinchero and Carlsson, {P. -A.} and O. Balmes and R. Felici and {van Rijn}, R. and Frenken, {J. W. M.} and Andersen, {Jesper N} and Edvin Lundgren and H. Gronbeck",

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doi = "10.1021/jz300069s",

language = "English",

volume = "3",

pages = "678--682",

journal = "The Journal of Physical Chemistry Letters",

issn = "1948-7185",

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TY - JOUR

T1 - The Active Phase of Palladium during Methane Oxidation

AU - Hellman, A.

AU - Resta, A.

AU - Martin, Natalia

AU - Gustafson, Johan

AU - Trinchero, A.

AU - Carlsson, P. -A.

AU - Balmes, O.

AU - Felici, R.

AU - van Rijn, R.

AU - Frenken, J. W. M.

AU - Andersen, Jesper N

AU - Lundgren, Edvin

AU - Gronbeck, H.

PY - 2012

Y1 - 2012

N2 - The active phase of Pd during methane oxidation is a long-standing puzzle, which, if solved, could provide routes for design of improved catalysts. Here, density functional theory and in situ surface X-ray diffraction are used to identify and characterize atomic sites yielding high methane conversion. Calculations are performed for methane dissociation over a range of Pd and PdOx surfaces and reveal facile dissociation on either under-coordinated Pd sites in PdO(101) or metallic surfaces. The experiments show unambiguously that high methane conversion requires sufficiently thick PdO(101) films or metallic Pd, in full agreement with the calculations. The established link between high activity and atomic structure enables rational design of improved catalysts.

AB - The active phase of Pd during methane oxidation is a long-standing puzzle, which, if solved, could provide routes for design of improved catalysts. Here, density functional theory and in situ surface X-ray diffraction are used to identify and characterize atomic sites yielding high methane conversion. Calculations are performed for methane dissociation over a range of Pd and PdOx surfaces and reveal facile dissociation on either under-coordinated Pd sites in PdO(101) or metallic surfaces. The experiments show unambiguously that high methane conversion requires sufficiently thick PdO(101) films or metallic Pd, in full agreement with the calculations. The established link between high activity and atomic structure enables rational design of improved catalysts.

U2 - 10.1021/jz300069s

DO - 10.1021/jz300069s

M3 - Article

C2 - 26286272

SN - 1948-7185

VL - 3

SP - 678

EP - 682

JO - The Journal of Physical Chemistry Letters

JF - The Journal of Physical Chemistry Letters

IS - 6

ER -

The Active Phase of Palladium during Methane Oxidation

Abstract

Subject classification (UKÄ)

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