DFT Studies of Palladium Model Catalysts: Structure and Size Effects

Ilya V. Yudanov; Alexander Genest; Notker Rösch

doi:10.1007/s10876-011-0392-4

DFT Studies of Palladium Model Catalysts: Structure and Size Effects

Ilya V. Yudanov, Alexander Genest, Notker Rösch

Associate Professorship of Theoretical Chemistry (2008 — 2024)

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

37 Scopus citations

Abstract

An important task for theory is the multi-scale modeling of catalytic properties of nanocrystallites with sizes ranging from clusters of few metal atoms to particles consisting of 10³-10⁴ atoms. To explore catalytic properties of nanosized metal catalysts, we developed an approach based on three-dimensional symmetric model clusters of 1-2 nm (~100 metal atoms) with fcc structure, terminated by low-index surfaces. With this modeling technique one is able to describe at an accurate DFT level various catalytic and adsorption properties of metal nanoparticles in quantitative agreement with experimental studies of model catalysts deposited on thin oxide films. Metal nanocrystallites exhibit properties that can significantly vary with their size and shape.

Original language	English
Pages (from-to)	433-448
Number of pages	16
Journal	Journal of Cluster Science
Volume	22
Issue number	3
DOIs	https://doi.org/10.1007/s10876-011-0392-4
State	Published - Sep 2011

Keywords

Density functional calculations
Nanocatalysts
Nanoparticles
Palladium

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10.1007/s10876-011-0392-4

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title = "DFT Studies of Palladium Model Catalysts: Structure and Size Effects",

abstract = "An important task for theory is the multi-scale modeling of catalytic properties of nanocrystallites with sizes ranging from clusters of few metal atoms to particles consisting of 103-104 atoms. To explore catalytic properties of nanosized metal catalysts, we developed an approach based on three-dimensional symmetric model clusters of 1-2 nm (~100 metal atoms) with fcc structure, terminated by low-index surfaces. With this modeling technique one is able to describe at an accurate DFT level various catalytic and adsorption properties of metal nanoparticles in quantitative agreement with experimental studies of model catalysts deposited on thin oxide films. Metal nanocrystallites exhibit properties that can significantly vary with their size and shape.",

keywords = "Density functional calculations, Nanocatalysts, Nanoparticles, Palladium",

author = "Yudanov, {Ilya V.} and Alexander Genest and Notker R{\"o}sch",

note = "Funding Information: Acknowledgments This work was supported in part by Deutsche Forschungsgemeinschaft, Fonds der Chemischen Industrie, the Russian Foundation for Basic Research, and the Siberian Branch of the Russian Academy of Sciences. We also acknowledge a generous allotment of computer time at Leibniz-Rechenzentrum M{\"u}nchen.",

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AU - Genest, Alexander

AU - Rösch, Notker

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N2 - An important task for theory is the multi-scale modeling of catalytic properties of nanocrystallites with sizes ranging from clusters of few metal atoms to particles consisting of 103-104 atoms. To explore catalytic properties of nanosized metal catalysts, we developed an approach based on three-dimensional symmetric model clusters of 1-2 nm (~100 metal atoms) with fcc structure, terminated by low-index surfaces. With this modeling technique one is able to describe at an accurate DFT level various catalytic and adsorption properties of metal nanoparticles in quantitative agreement with experimental studies of model catalysts deposited on thin oxide films. Metal nanocrystallites exhibit properties that can significantly vary with their size and shape.

AB - An important task for theory is the multi-scale modeling of catalytic properties of nanocrystallites with sizes ranging from clusters of few metal atoms to particles consisting of 103-104 atoms. To explore catalytic properties of nanosized metal catalysts, we developed an approach based on three-dimensional symmetric model clusters of 1-2 nm (~100 metal atoms) with fcc structure, terminated by low-index surfaces. With this modeling technique one is able to describe at an accurate DFT level various catalytic and adsorption properties of metal nanoparticles in quantitative agreement with experimental studies of model catalysts deposited on thin oxide films. Metal nanocrystallites exhibit properties that can significantly vary with their size and shape.

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DFT Studies of Palladium Model Catalysts: Structure and Size Effects

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Keywords

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