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Water Oxidation by Electrodeposited Cobalt Oxides—Role of Anions and Redox‐Inert Cations in Structure and Function of the Amorphous Catalyst
Author(s) -
Risch Marcel,
Klingan Katharina,
Ringleb Franziska,
Chernev Petko,
Zaharieva Ivelina,
Fischer Anna,
Dau Holger
Publication year - 2012
Publication title -
chemsuschem
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.412
H-Index - 157
eISSN - 1864-564X
pISSN - 1864-5631
DOI - 10.1002/cssc.201100574
Subject(s) - chemistry , catalysis , redox , x ray absorption spectroscopy , inorganic chemistry , cobalt , electrochemistry , electrocatalyst , aqueous solution , prussian blue , absorption spectroscopy , potassium , organic chemistry , physics , electrode , quantum mechanics
For the production of nonfossil fuels, water oxidation by inexpensive cobalt‐based catalysts is of high interest. Films for the electrocatalysis of water oxidation were obtained by oxidative self‐assembly (electrodeposition) from aqueous solutions containing, apart from Co, either K, Li or Ca with either a phosphate, acetate or chloride anion. X‐ray absorption spectroscopy (XAS) at the Co K ‐edge revealed clusters of edge‐sharing CoO 6 octahedra in all films, but the size or structural disorder of the Co‐oxido clusters differed. Whereas potassium binding is largely unspecific, CaCo 3 O 4 cubanes, which resemble the CaMn 3 O 4 cubane of the biological catalyst in oxygenic photosynthesis, may form, as suggested by XAS at the Ca K ‐edge. Cyclic voltammograms in a potassium phosphate buffer at pH 7 revealed that no specific combination of anions and redox‐inactive cations is required for catalytic water oxidation. However, the anion type modulates not only the size (or order) of the Co‐oxido clusters, but also electrodeposition rates, redox potentials, the capacity for oxidative charging, and catalytic currents. On these grounds, structure–activity relations are discussed.