Photocatalytic Water Splitting for Solar Hydrogen Production Using the Carbonate Effect and the Z‐Scheme Reaction

The development of innovative technologies for solar energy conversion and storage is important for solving the global warming problem and for establishing a sustainable society. The photocatalytic water‐splitting reaction using semiconductor powders has been intensively studied as a promising techn...

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Veröffentlicht in:Advanced energy materials 2019-06, Vol.9 (23), p.n/a
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description The development of innovative technologies for solar energy conversion and storage is important for solving the global warming problem and for establishing a sustainable society. The photocatalytic water‐splitting reaction using semiconductor powders has been intensively studied as a promising technology for direct and simple solar energy conversion. However, the evolution of H2 and O2 gases in a stoichiometric ratio (H2/O2 = 2) is very difficult owing to various issues, such as an unfavorable backward reaction and mismatched band potentials. Two important findings have widened the variety of photocatalysts available for stoichiometric water‐splitting, viz. the carbonate anion effect and the Z‐scheme photocatalytic reaction using a redox mediator. The bicarbonate anion has been found to act as a redox catalyst via preferential peroxide formation and subsequent decomposition to O2. As the Z‐scheme reaction using a redox mediator mitigates band potential mismatches, it is widely applicable for various visible‐light‐active photocatalysts. This review describes the development of photocatalytic water‐splitting for solar hydrogen production using the carbonate anion effect and the Z‐scheme reaction. Moreover, recent developments in photocatalysis–electrolysis hybrid systems, an advanced Z‐scheme reaction concept, are also reviewed for practical and economical hydrogen production. Photocatalytic solar energy conversion techniques are candidates for solving global warming and energy shortage issues. This paper reviews the development of photocatalytic water splitting for solar hydrogen production using the carbonate anion effect and the Z‐scheme reaction. Moreover, for practical and economical hydrogen production, recent developments in photocatalysis–electrolysis hybrid systems, an advanced Z‐scheme reaction concept, are also reviewed.
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This review describes the development of photocatalytic water‐splitting for solar hydrogen production using the carbonate anion effect and the Z‐scheme reaction. Moreover, recent developments in photocatalysis–electrolysis hybrid systems, an advanced Z‐scheme reaction concept, are also reviewed for practical and economical hydrogen production. Photocatalytic solar energy conversion techniques are candidates for solving global warming and energy shortage issues. This paper reviews the development of photocatalytic water splitting for solar hydrogen production using the carbonate anion effect and the Z‐scheme reaction. 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subjects Anions
Bicarbonates
Decomposition reactions
Electrolysis
Energy storage
Hybrid systems
hydrogen
Hydrogen production
Photocatalysis
Photocatalysts
redox mediators
Solar energy
Solar energy conversion
solar fuels
Water splitting
title Photocatalytic Water Splitting for Solar Hydrogen Production Using the Carbonate Effect and the Z‐Scheme Reaction
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