Modeling metal adsorption at amorphous silica: Gold atoms and dimers as example

Kok Hwa Lim; Olga Zakharieva; Alexei M. Shor; Notker Rösch

doi:10.1016/j.cplett.2007.07.021

Modeling metal adsorption at amorphous silica: Gold atoms and dimers as example

Kok Hwa Lim, Olga Zakharieva, Alexei M. Shor, Notker Rösch

Professur für Theoretische Chemie (2008 — 2024)

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

22 Zitate (Scopus)

Abstract

For Au and Au₂ species at three types of defects as adsorption sites (non-bridging oxygen centers, silanolate groups, E′ centers), we carried out periodic supercell DFT calculations to compare two models of amorphous silica, derived from the walls of MCM-41 or from edingtonite. For atomic adsorption, both types of models afforded similar adsorption geometries and binding energies. Striking differences were found for Au₂ adsorption, where the structural characteristics of edingtonite automatically lead to simultaneous interactions of adsorbates with neighboring sites, whereas the MCM models allowed the structural isolation of defects, hence are more flexible when one wants to describe varying defect densities.

Originalsprache	Englisch
Seiten (von - bis)	280-286
Seitenumfang	7
Fachzeitschrift	Chemical Physics Letters
Jahrgang	444
Ausgabenummer	4-6
DOIs	https://doi.org/10.1016/j.cplett.2007.07.021
Publikationsstatus	Veröffentlicht - 27 Aug. 2007

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10.1016/j.cplett.2007.07.021

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title = "Modeling metal adsorption at amorphous silica: Gold atoms and dimers as example",

abstract = "For Au and Au2 species at three types of defects as adsorption sites (non-bridging oxygen centers, silanolate groups, E′ centers), we carried out periodic supercell DFT calculations to compare two models of amorphous silica, derived from the walls of MCM-41 or from edingtonite. For atomic adsorption, both types of models afforded similar adsorption geometries and binding energies. Striking differences were found for Au2 adsorption, where the structural characteristics of edingtonite automatically lead to simultaneous interactions of adsorbates with neighboring sites, whereas the MCM models allowed the structural isolation of defects, hence are more flexible when one wants to describe varying defect densities.",

author = "Lim, {Kok Hwa} and Olga Zakharieva and Shor, {Alexei M.} and Notker R{\"o}sch",

note = "Funding Information: K.H.L. is grateful to Deutscher Akademischer Austauschdienst for a fellowship. This work was supported by an integration project of the Siberian Branch of the Russian Academy of Sciences (Grant No. 79), Deutsche Forschungsgemeinschaft, and Fonds der Chemischen Industrie. ",

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doi = "10.1016/j.cplett.2007.07.021",

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AU - Shor, Alexei M.

AU - Rösch, Notker

N1 - Funding Information: K.H.L. is grateful to Deutscher Akademischer Austauschdienst for a fellowship. This work was supported by an integration project of the Siberian Branch of the Russian Academy of Sciences (Grant No. 79), Deutsche Forschungsgemeinschaft, and Fonds der Chemischen Industrie.

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Y1 - 2007/8/27

N2 - For Au and Au2 species at three types of defects as adsorption sites (non-bridging oxygen centers, silanolate groups, E′ centers), we carried out periodic supercell DFT calculations to compare two models of amorphous silica, derived from the walls of MCM-41 or from edingtonite. For atomic adsorption, both types of models afforded similar adsorption geometries and binding energies. Striking differences were found for Au2 adsorption, where the structural characteristics of edingtonite automatically lead to simultaneous interactions of adsorbates with neighboring sites, whereas the MCM models allowed the structural isolation of defects, hence are more flexible when one wants to describe varying defect densities.

AB - For Au and Au2 species at three types of defects as adsorption sites (non-bridging oxygen centers, silanolate groups, E′ centers), we carried out periodic supercell DFT calculations to compare two models of amorphous silica, derived from the walls of MCM-41 or from edingtonite. For atomic adsorption, both types of models afforded similar adsorption geometries and binding energies. Striking differences were found for Au2 adsorption, where the structural characteristics of edingtonite automatically lead to simultaneous interactions of adsorbates with neighboring sites, whereas the MCM models allowed the structural isolation of defects, hence are more flexible when one wants to describe varying defect densities.

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Modeling metal adsorption at amorphous silica: Gold atoms and dimers as example

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