Crystal Facet Engineering of Photoelectrodes for Photoelectrochemical Water Splitting

Wang, Songcan; Liu, Gang; Wang, Luyao

doi:10.1021/acs.chemrev.8b00584

Cited by 684 publications

(437 citation statements)

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“…100 nm), and slow water oxidation kinetics. [7] Plenty of approaches have been attempted to overcome these limitations,i ncluding element doping, [8] morphology engineering, [9] heterostructure formation, [10] oxygen evolution catalysts (OECs)-layer loading, [11] crystal facet engineering, [12] plasmonic enhancement, [13] and combinations thereof.However, the efficiency of BiVO 4 photoanodes is still far from an application level. [5a] Beside these well-studied techniques,aseries of postsynthetic treatments,aconcept proposed by Smith and Stefik, have recently emerged as as imple and effective strategy to enhance the intrinsic photocatalytic activity of BiVO 4 photoanodes.…”

Section: Introductionmentioning

confidence: 99%

Efficient BiVO₄ Photoanodes by Postsynthetic Treatment: Remarkable Improvements in Photoelectrochemical Performance from Facile Borate Modification

et al. 2019

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Water‐splitting photoanodes based on semiconductor materials typically require a dopant in the structure and co‐catalysts on the surface to overcome the problems of charge recombination and high catalytic barrier. Unlike these conventional strategies, a simple treatment is reported that involves soaking a sample of pristine BiVO4 in a borate buffer solution. This modifies the catalytic local environment of BiVO4 by the introduction of a borate moiety at the molecular level. The self‐anchored borate plays the role of a passivator in reducing the surface charge recombination as well as that of a ligand in modifying the catalytic site to facilitate faster water oxidation. The modified BiVO4 photoanode, without typical doping or catalyst modification, achieved a photocurrent density of 3.5 mA cm−2 at 1.23 V and a cathodically shifted onset potential of 250 mV. This work provides an extremely simple method to improve the intrinsic photoelectrochemical performance of BiVO4 photoanodes.

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Section: Introductionmentioning

confidence: 99%

Efficient BiVO₄ Photoanodes by Postsynthetic Treatment: Remarkable Improvements in Photoelectrochemical Performance from Facile Borate Modification

et al. 2019

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“…Systems based on ferroelectric–semiconductor, typically requiring an external energy for polarization pretreatment, also suffers from a limitation of degeneration with the polarized built‐in electric field over time . “Crystal plane engineering” is an efficient method for exposing different crystal planes in a nanoparticle, which aids in achieving difference surface potentials at various planes ascribed to the varied atomic arrangements . Using this strategy, a polarizing electric field can be induced between crystal planes.…”

mentioning

confidence: 99%

“…[11][12][13] "Crystal plane engineering" is an efficient method for exposing different crystal planes in a nanoparticle, which aids in achieving difference surface potentials at various planes ascribed to the varied atomic arrangements. [6,[14][15][16] Using this strategy, a polarizing electric field can be induced between crystal planes. Hence, by exploiting crystal planes' electric filed to orient ferroelectric dipole in a nanoparticle, it is possible to drive photocatalyst water splitting without extra energy for polarization and enhance the photogenerated charge's mobility.…”

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confidence: 99%

A Hybrid Artificial Photocatalysis System Splits Atmospheric Water for Simultaneous Dehumidification and Power Generation

et al. 2019

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A new approach for artificial photocatalysis of electrical generation directly from atmospheric water is reported. A hybrid system comprising a hydrogel incorporated with Cu2O and BaTiO3 nanoparticles is developed, wherein the Cu2O is designed to expose two different crystal planes, namely (100) and (111). These planes exhibit different surface potentials and form a polarization electric field of 2.3 kV cm−1 that acts on a ferroelectric dipole. With the help of this electric field, the dipole is redirected for aiding in positive and negative polarizations with (100) and (111) planes, then boosting water reduction and oxidation kinetics separately at (100) and (111) planes. Additonally, zinc‐/cobalt‐based superhygroscopic hydrogels serve as a water‐capturing “hand” to harness humidity from the ambient environment. The integrated hydrogel–Cu2O@BaTiO3 hybrid is used to dehumidify air, which can split 36.5 mg of water by employing only 150 mg hydrogel and simultaneously generate a photocurrent of 224.3 µA cm−2 under 10 mW cm−2 illumination.

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“…Collection of hydrogen in the form of a hydride opens, more generally, the prospect of subsequently using such materials as anodes in batteries employing oxygen reduction cathodes.Photocatalytic water splitting is widely investigated as a promising means for sustainable fuel generation using sunlight. [1][2][3][4][5] When the splitting process is conducted via suspensions of Adv. Energy…”

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confidence: 99%

Highly Efficient Sunlight‐Driven Seawater Splitting in a Photoelectrochemical Cell with Chlorine Evolved at Nanostructured WO₃ Photoanode and Hydrogen Stored as Hydride within Metallic Cathode

Jadwiszczak

Jakubow‐Piotrowska

Kędzierzawski

et al. 2019

Advanced Energy Materials

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semiconductor photocatalytic particles, pure water is generally used and both reduction and oxidation reaction products, H 2 and O 2 , are formed in the same cell compartment and should be subsequently separated. [2,3] On the other hand, employing a photoelectrolysis cell with separated anodic and cathodic compartments imposes use of a supporting electrolyte with ionic conductivity large enough to avoid excessive Ohmic losses within the cell. [4,6] The choice of the appropriate electrolyte is even more important when relatively thick nanoporous film photoelectrodes with high internal photoactive surface area are employed, where too low conductivity of the electrolyte may adversely affect the amount of collected photocurrent due to uneven current distribution across the semiconductor film. [7] Consequently, in addition to pure water, also the chemicals required to prepare electrolyte for the photoelectrolysis cell will potentially constitute a nonnegligible part of the operational cost of larger scale photoelectrochemical (PEC) water splitting devices. The fact that cannot at all be neglected-extensive utilization for electrolysis of fresh water would put heavy pressure on vital water resources.Since the seawater is a free and widely abundant electrolyte, there were various attempts to use it in the PEC [8][9][10][11][12][13] and conventional electrochemical [14] devices to produce hydrogen. From the practical viewpoint, the photoelectrolysis of seawater requires at first identification of photoanode materials stable in the presence of chloride ions under highly oxidizing conditions. Only few among works reported on the PEC seawater splitting describe experiments conducted under visible light irradiation. An electrode consisting of molybdenum-doped bismuth vanadate (Mo-BiVO 4 ) reached, under simulated AM 1.5G (100 mW cm −2 ) illumination, a photocurrent of 2.2 mA cm −2 at 1 V versus RHE (reversible hydrogen electrode). [9] Loading the Mo-BiVO 4 electrode with precious metal RhO 2 catalyst was effective in limiting to ≈10% the drop of the photocurrent over a 5 h long stability test. Analysis of the photoelectrolysis A seawater splitting photoelectrochemical cell featuring a nanostructured tungsten trioxide photoanode that exhibits very high and stable photocurrents producing chlorine with average 70% Faradaic efficiency is described. Fabrication of the WO 3 electrodes on fluorine-doped tin oxide substrates involves a simple solution-based method and sequential layer-by-layer deposition with a progressively adjusted amount of structure-directing agent in the precursor and a two-step annealing. Such a procedure allows tailoring of thick, highly porous, structurally stable WO 3 films with a large internal photoactive surface area optimizing utilization of visible light wavelengths by the photoanode. With the application of an anodic potential of 0.76 V versus Ag/AgCl reference electrode (0.4 V below the thermodynamic Cl 2 /Cl − potential) in synthetic seawater, the designed WO 3 photoanodes irradiated with simulated ...

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Crystal Facet Engineering of Photoelectrodes for Photoelectrochemical Water Splitting

Cited by 684 publications

References 482 publications

Efficient BiVO₄ Photoanodes by Postsynthetic Treatment: Remarkable Improvements in Photoelectrochemical Performance from Facile Borate Modification

Efficient BiVO₄ Photoanodes by Postsynthetic Treatment: Remarkable Improvements in Photoelectrochemical Performance from Facile Borate Modification

A Hybrid Artificial Photocatalysis System Splits Atmospheric Water for Simultaneous Dehumidification and Power Generation

Highly Efficient Sunlight‐Driven Seawater Splitting in a Photoelectrochemical Cell with Chlorine Evolved at Nanostructured WO₃ Photoanode and Hydrogen Stored as Hydride within Metallic Cathode

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Crystal Facet Engineering of Photoelectrodes for Photoelectrochemical Water Splitting

Cited by 684 publications

References 482 publications

Efficient BiVO4 Photoanodes by Postsynthetic Treatment: Remarkable Improvements in Photoelectrochemical Performance from Facile Borate Modification

Efficient BiVO4 Photoanodes by Postsynthetic Treatment: Remarkable Improvements in Photoelectrochemical Performance from Facile Borate Modification

A Hybrid Artificial Photocatalysis System Splits Atmospheric Water for Simultaneous Dehumidification and Power Generation

Highly Efficient Sunlight‐Driven Seawater Splitting in a Photoelectrochemical Cell with Chlorine Evolved at Nanostructured WO3 Photoanode and Hydrogen Stored as Hydride within Metallic Cathode

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Efficient BiVO₄ Photoanodes by Postsynthetic Treatment: Remarkable Improvements in Photoelectrochemical Performance from Facile Borate Modification

Efficient BiVO₄ Photoanodes by Postsynthetic Treatment: Remarkable Improvements in Photoelectrochemical Performance from Facile Borate Modification

Highly Efficient Sunlight‐Driven Seawater Splitting in a Photoelectrochemical Cell with Chlorine Evolved at Nanostructured WO₃ Photoanode and Hydrogen Stored as Hydride within Metallic Cathode