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Literature DB >> 33998763

Surface oxygen Vacancies on Reduced Co₃ O₄ (100): Superoxide Formation and Ultra-Low-Temperature CO Oxidation.

Yun Liu¹, Yuman Peng², Mathias Naschitzki¹, Sandy Gewinner³, Wieland Schöllkopf³, Helmut Kuhlenbeck¹, Rossitza Pentcheva², Beatriz Roldan Cuenya¹.

Abstract

The activation of molecular oxygen is a fundamental step in almost all catalytic oxidation reactions. We have studied this topic and the role of surface vacancies for Co3 O4 (100) films with a synergistic combination of experimental and theoretical methods. We show that the as-prepared surface is B-layer terminated and that mild reduction produces oxygen single and double vacancies in this layer. Oxygen adsorption experiments clearly reveal different superoxide species below room temperature. The superoxide desorbs below ca. 120 K from a vacancy-free surface and is not active for CO oxidation while superoxide on a surface with oxygen vacancies is stable up to ca. 270 K and can oxidize CO already at the low temperature of 120 K. The vacancies are not refilled by oxygen from the superoxide, which makes them suitable for long-term operation. Our joint experimental/theoretical effort highlights the relevance of surface vacancies in catalytic oxidation reactions.

Entities: Chemical Species

Keywords: Co3O4; O2 activation; oxide surfaces; oxygen vacancies; surface chemistry

Year: 2021 PMID： 33998763 DOI： 10.1002/anie.202103359

Source DB: PubMed Journal: Angew Chem Int Ed Engl ISSN： 1433-7851 Impact factor: 15.336

3 in total

1. Activation of Molecular O₂ on CoFe₂ O₄ (001) Surfaces: An Embedded Cluster Study.

Authors: Arjeta Rushiti; Christof Hättig
Journal: Chemistry Date: 2021-11-08 Impact factor: 5.020

2. Direct Visualisation of the Surface Atomic Active Sites of Carbon-Supported Co₃ O₄ Nanocrystals via High-Resolution Phase Restoration.

Authors: Ofentse A Makgae; Arthur N Moya; Tumelo N Phaahlamohlaka; Chen Huang; Neil J Coville; Angus I Kirkland; Emanuela Liberti
Journal: Chemphyschem Date: 2022-06-01 Impact factor: 3.520

3. Adatom Bonding Sites in a Nickel-Fe₃ O₄ (001) Single-Atom Model Catalyst and O₂ Reactivity Unveiled by Surface Action Spectroscopy with Infrared Free-Electron Laser Light.

Authors: Yun Liu; Zhongkang Han; Sandy Gewinner; Wieland Schöllkopf; Sergey V Levchenko; Helmut Kuhlenbeck; Beatriz Roldan Cuenya
Journal: Angew Chem Int Ed Engl Date: 2022-05-19 Impact factor: 16.823

3 in total

Surface oxygen Vacancies on Reduced Co3 O4 (100): Superoxide Formation and Ultra-Low-Temperature CO Oxidation.

1. Activation of Molecular O2 on CoFe2 O4 (001) Surfaces: An Embedded Cluster Study.

2. Direct Visualisation of the Surface Atomic Active Sites of Carbon-Supported Co3 O4 Nanocrystals via High-Resolution Phase Restoration.

3. Adatom Bonding Sites in a Nickel-Fe3 O4 (001) Single-Atom Model Catalyst and O2 Reactivity Unveiled by Surface Action Spectroscopy with Infrared Free-Electron Laser Light.

Surface oxygen Vacancies on Reduced Co₃ O₄ (100): Superoxide Formation and Ultra-Low-Temperature CO Oxidation.

1. Activation of Molecular O₂ on CoFe₂ O₄ (001) Surfaces: An Embedded Cluster Study.

2. Direct Visualisation of the Surface Atomic Active Sites of Carbon-Supported Co₃ O₄ Nanocrystals via High-Resolution Phase Restoration.

3. Adatom Bonding Sites in a Nickel-Fe₃ O₄ (001) Single-Atom Model Catalyst and O₂ Reactivity Unveiled by Surface Action Spectroscopy with Infrared Free-Electron Laser Light.