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Literature DB >> 26245626

Catalytic Oxygen Evolution by Cobalt Oxido Thin Films.

D Kwabena Bediako¹, Andrew M Ullman¹, Daniel G Nocera².

Abstract

The contemporary demand to generate fuels from solar energy has stimulated intense effort to develop water splitting catalysts that can be coupled to light-absorbing materials. Cobalt oxido catalyst (Co-OECs) films deposited from buffered Co(II) solutions have emerged as arguably the most studied class of heterogeneous oxygen evolution catalysts. The interest in these materials stems from their formation by self-assembly, their self-healing properties, and their promising catalytic activity under a variety of conditions. The structure and function of these catalysts are reviewed here together with studies of molecular Co-O cluster compounds, which have proven invaluable in elucidating the chemistry of the Co-OECs.

Entities: Chemical Gene

Keywords: Artificial leaf; Cluster compounds; Cobalt oxide; Electrocatalysis; Oxygen evolution reaction; Proton-coupled electron transfer; Self-assembly; Self-healing; Solar fuels; Water splitting

Year: 2016 PMID： 26245626 DOI： 10.1007/128_2015_649

Source DB: PubMed Journal: Top Curr Chem ISSN： 0340-1022

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Cited

7 in total

1. Continuous electrochemical water splitting from natural water sources via forward osmosis.

Authors: Samuel S Veroneau; Daniel G Nocera
Journal: Proc Natl Acad Sci U S A Date: 2021-03-02 Impact factor: 11.205

2. In situ characterization of cofacial Co(IV) centers in Co₄O₄ cubane: Modeling the high-valent active site in oxygen-evolving catalysts.

Authors: Casey N Brodsky; Ryan G Hadt; Dugan Hayes; Benjamin J Reinhart; Nancy Li; Lin X Chen; Daniel G Nocera
Journal: Proc Natl Acad Sci U S A Date: 2017-03-27 Impact factor: 11.205

Catalytic Oxygen Evolution by Cobalt Oxido Thin Films.

1. Continuous electrochemical water splitting from natural water sources via forward osmosis.

2. In situ characterization of cofacial Co(IV) centers in Co₄O₄ cubane: Modeling the high-valent active site in oxygen-evolving catalysts.

3. Ambient nitrogen reduction cycle using a hybrid inorganic-biological system.

4. Efficient electrolyzer for CO2 splitting in neutral water using earth-abundant materials.

5. Detection of high-valent iron species in alloyed oxidic cobaltates for catalysing the oxygen evolution reaction.

6. Design of template-stabilized active and earth-abundant oxygen evolution catalysts in acid.

Review 7. Self-healing oxygen evolution catalysts.

Catalytic Oxygen Evolution by Cobalt Oxido Thin Films.

1. Continuous electrochemical water splitting from natural water sources via forward osmosis.

2. In situ characterization of cofacial Co(IV) centers in Co4O4 cubane: Modeling the high-valent active site in oxygen-evolving catalysts.

3. Ambient nitrogen reduction cycle using a hybrid inorganic-biological system.

4. Efficient electrolyzer for CO2 splitting in neutral water using earth-abundant materials.

5. Detection of high-valent iron species in alloyed oxidic cobaltates for catalysing the oxygen evolution reaction.

6. Design of template-stabilized active and earth-abundant oxygen evolution catalysts in acid.

Review 7. Self-healing oxygen evolution catalysts.

2. In situ characterization of cofacial Co(IV) centers in Co₄O₄ cubane: Modeling the high-valent active site in oxygen-evolving catalysts.