A computational study of H2 dissociation on silver surfaces: The effect of oxygen in the added row structure of Ag(110)

Amjad B. Mohammad; Kok Hwa Lim; Ilya V. Yudanov; Konstantin M. Neyman; Notker Rösch

doi:10.1039/b616675j

A computational study of H₂ dissociation on silver surfaces: The effect of oxygen in the added row structure of Ag(110)

Amjad B. Mohammad, Kok Hwa Lim, Ilya V. Yudanov, Konstantin M. Neyman, Notker Rösch

Professur für Theoretische Chemie (2008 — 2024)

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

44 Zitate (Scopus)

Abstract

We studied computationally the activation of H₂ on clean planar (111), (110) and stepped (221) as well as oxygen pre-covered silver surfaces using a density functional slab model approach. In line with previous data we determined clean silver to be inert towards H₂ dissociation, both thermodynamically and kinetically. The reaction is endothermic by ∼40 kJ mol^-1 and exhibits high activation energies of ∼125 kJ mol ^-1. However, oxygen on the surface, modeled by the reconstructed surface p(2 × 1)O/Ag(110) that exhibits -O-Ag-O- added rows, renders H₂ dissociation clearly exothermic and kinetically feasible. The reaction was calculated to proceed in two steps: first the H-H bond is broken at an Ag-O pair with an activation barrier E_a ∼70 kJ mol ^-1, then the H atom bound at an Ag center migrates to a neighboring O center with E_a ∼12 kJ mol^-1. This journal is

Originalsprache	Englisch
Seiten (von - bis)	1247-1254
Seitenumfang	8
Fachzeitschrift	Physical Chemistry Chemical Physics
Jahrgang	9
Ausgabenummer	10
DOIs	https://doi.org/10.1039/b616675j
Publikationsstatus	Veröffentlicht - 2007

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abstract = "We studied computationally the activation of H2 on clean planar (111), (110) and stepped (221) as well as oxygen pre-covered silver surfaces using a density functional slab model approach. In line with previous data we determined clean silver to be inert towards H2 dissociation, both thermodynamically and kinetically. The reaction is endothermic by ∼40 kJ mol-1 and exhibits high activation energies of ∼125 kJ mol -1. However, oxygen on the surface, modeled by the reconstructed surface p(2 × 1)O/Ag(110) that exhibits -O-Ag-O- added rows, renders H2 dissociation clearly exothermic and kinetically feasible. The reaction was calculated to proceed in two steps: first the H-H bond is broken at an Ag-O pair with an activation barrier Ea ∼70 kJ mol -1, then the H atom bound at an Ag center migrates to a neighboring O center with Ea ∼12 kJ mol-1. This journal is",

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T2 - The effect of oxygen in the added row structure of Ag(110)

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AU - Lim, Kok Hwa

AU - Yudanov, Ilya V.

AU - Neyman, Konstantin M.

AU - Rösch, Notker

PY - 2007

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AB - We studied computationally the activation of H2 on clean planar (111), (110) and stepped (221) as well as oxygen pre-covered silver surfaces using a density functional slab model approach. In line with previous data we determined clean silver to be inert towards H2 dissociation, both thermodynamically and kinetically. The reaction is endothermic by ∼40 kJ mol-1 and exhibits high activation energies of ∼125 kJ mol -1. However, oxygen on the surface, modeled by the reconstructed surface p(2 × 1)O/Ag(110) that exhibits -O-Ag-O- added rows, renders H2 dissociation clearly exothermic and kinetically feasible. The reaction was calculated to proceed in two steps: first the H-H bond is broken at an Ag-O pair with an activation barrier Ea ∼70 kJ mol -1, then the H atom bound at an Ag center migrates to a neighboring O center with Ea ∼12 kJ mol-1. This journal is

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