Low Catalyst Loading Enhances Charge Accumulation for Photoelectrochemical Water Splitting

Solar water oxidation is a critical step in artificial photosynthesis. Successful completion of the process requires four holes and releases four protons. It depends on the consecutive accumulation of charges at the active site. While recent research has shown an obvious dependence of the reaction k...

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Bibliographic Details
Published in:Angewandte Chemie (International ed.) 2023-08, Vol.62 (34), p.e202307909-n/a
Main Authors: Liu, Tianying, Li, Wei, Wang, David Z., Luo, Tongtong, Fei, Muchun, Shin, Dongyoon, Waegele, Matthias M., Wang, Dunwei
Format: Article
Language:English
Subjects:
Accumulation
Catalysts
Charge transfer
Chemical reactions
Density
Hematite
Kinetics
Oxidation
Photocatalysis
Photoelectrochemistry
Photons
Photosynthesis
Protons
Reaction kinetics
Recombination
Surface charge
Water Splitting
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Summary:Solar water oxidation is a critical step in artificial photosynthesis. Successful completion of the process requires four holes and releases four protons. It depends on the consecutive accumulation of charges at the active site. While recent research has shown an obvious dependence of the reaction kinetics on the hole concentrations on the surface of heterogeneous (photo)electrodes, little is known about how the catalyst density impacts the reaction rate. Using atomically dispersed Ir catalysts on hematite, we report a study on how the interplay between the catalyst density and the surface hole concentration influences the reaction kinetics. At low photon flux, where surface hole concentrations are low, faster charge transfer was observed on photoelectrodes with low catalyst density compared to high catalyst density; at high photon flux and high applied potentials, where surface hole concentrations are moderate or high, slower surface charge recombination was afforded by low‐density catalysts. The results support that charge transfer between the light absorber and the catalyst is reversible; they reveal the unexpected benefits of low‐density catalyst loading in facilitating forward charge transfer for desired chemical reactions. It is implied that for practical solar water splitting devices, a suitable catalyst loading is important for maximized performance. Water oxidation requires consecutive accumulation of charges at the catalytically active site. The active centers compete with each other in accumulating charges. The unexpected benefits of low‐density catalyst loading in facilitating forward charge transfer for desired chemical reactions were revealed. It is implied that for practical solar water splitting devices, a suitable catalyst loading is important for optimized performance.
ISSN:1433-7851
1521-3773
DOI:10.1002/anie.202307909