Sunlight Selective Photodeposition of CoOx(OH)y and NiOx(OH)y on Truncated Bipyramidal BiVO4 for Highly Efficient Photocatalysis

Hermans, Yannick; Olivier, Céline; Junge, Henrik; Klein, Andreas; Jaegermann, Wolfram; Toupance, Thierry

doi:10.1021/acsami.0c14624

Cited by 20 publications

(14 citation statements)

References 78 publications

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“…The O 2 evolution rate for the 3DOM BiVO 4 is ∼660 μmol h –1 g –1 (for 0.05 g of photocatalyst), which is on par with the best performing BiVO 4 photocatalyst (Table S1). − Furthermore, the 3DOM BiVO 4 sample exhibits a higher anodic photocurrent density than the platelike BiVO 4 (Figure b), which also agrees well with the trend of photocatalytic gas evolution activities. Interestingly, a more negative onset potential and a sharper increase of photocurrent density between 0.4 and 0.6 V versus reversible hydrogen electrode (RHE) were observed for the 3DOM BiVO 4 , which is possibly ascribed to their different surface work functions .…”

supporting

confidence: 77%

Unveiling Carrier Dynamics in Periodic Porous BiVO₄ Photocatalyst for Enhanced Solar Water Splitting

Irani

Zhang

et al. 2021

ACS Energy Lett.

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Improved photocatalytic activities in highly ordered porous photocatalysts are often attributed to the larger surface area, higher light absorption, and suppressed charge recombination. Other underlying reasons for the improved charge transport, however, remain elusive at this stage. Herein, 3DOM BiVO 4 photocatalysts are examined to understand the carrier dynamics and their effects in photocatalytic water splitting. Quantum confinement arising from the ultrathin and crystalline wall upshifted its conduction band, enabling photocatalytic proton reduction to hydrogen gas under visible-light illumination. Time-resolved microwave conductivity spectroscopy reveals its ∼6 times higher charge mobility and longer charge diffusion length relative to the bulk counterpart. The long lifetime (∼360 ns) of 3DOM BiVO 4 with a power-law decay suggests the improved charge separation and the formation of shallow trapping states. Further investigation by Kelvin probe force microscope discloses a built-in electric field with upward band bending from the internal wall to the interconnection part of 3DOM BiVO 4 .

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supporting

confidence: 77%

Unveiling Carrier Dynamics in Periodic Porous BiVO₄ Photocatalyst for Enhanced Solar Water Splitting

Irani

Zhang

et al. 2021

ACS Energy Lett.

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“…According to the elemental composition, these reduction cocatalysts can be further classified as elemental metals (e.g., Ni, [ 29 ] Cu, [18b] and CoNi alloy [ 30 ] ), metal sulfides (e.g., MoS 2 , [ 31 ] NiS, [ 32 ] and CoMoS x [ 33 ] ), metal phosphides (e.g., Ni 2 P, [ 34 ] CoP, [ 35 ] and NiFeP [ 36 ] ), metal nitrides (e.g., Ni 3 N [24a] and Co 3 N [ 37 ] ), metal carbides (e.g., Ni 3 C [ 38 ] and Mo 2 C [ 39 ] ), metal borides (e.g., NiB [ 40 ] and NiCoB [ 41 ] ), metal oxides (e.g., NiO [ 42 ] and CuO [ 43 ] ), and metal hydroxides (e.g., Ni(OH) 2 [ 44 ] and Cu(OH) 2 [ 45 ] ) (Figure 1). In comparison, a few transition‐metal‐based cocatalysts are utilized as oxidation cocatalysts, involving the metals (e.g., Co [ 46 ] and Mn [ 47 ] ), oxides (e.g., CoO x [ 48 ] and MnO x [ 49 ] ), hydroxides (e.g., Co(OH) 2 [ 50 ] and Fe(OH) 3 [ 51 ] ), oxyhydroxides (e.g., FeOOH [ 52 ] and CoOOH [ 53 ] ), and phosphates (e.g., Co‐Pi [ 54 ] and CoNi‐Pi [27b] ), also as shown in Figure 1.…”

Section: Fundamentals Of Transition‐metal‐based Cocatalysts For Photo...mentioning

confidence: 99%

“…Transition metal hydroxides and oxyhydroxides have strong adsorption and hydrogen bonding interactions toward water molecules, therefore they could be utilized as promising oxidation cocatalysts on semiconductor photocatalysts to improve the photocatalytic water splitting performance. [ 388 ] Up to now, a few metal hydroxides such as cobalt hydroxide, [ 50,371 ] nickel hydroxide, [ 388 ] iron hydroxide, [ 51 ] and bimetal layered hydroxides [ 372–374 ] as well as some metal oxyhydroxides including iron oxyhydroxide, [21a,52,376,389] cobalt oxyhydroxide, [21b,21c,53,375] and nickel oxyhydroxide [ 53 ] have been investigated as cocatalysts for photocatalytic water oxidation. Since these hydroxides and oxyhydroxides have semiconducting properties, when they are supported on the surface of semiconductors, heterojunctions are inclined to be formed to accelerate the separation and transfer of photoinduced holes.…”

Section: Transition‐metal‐based Oxidation Cocatalysts For Photocataly...mentioning

confidence: 99%

“…Furthermore, the oxyhydroxides based on nickel and cobalt components have been developed as cocatalysts as well. For instance, Toupance et al [ 53 ] investigated the cocatalytic performance of CoO x (OH) y and NiO x (OH) y cocatalysts on BiVO 4 in photocatalytic O 2 evolution. They found CoO x (OH) y loaded BiVO 4 showed significantly higher performance for O 2 evolution in contrast that of NiO x (OH) y loaded BiVO 4 , achieving a maximum rate of up to 1538 μmol h −1 g −1 .…”

Section: Transition‐metal‐based Oxidation Cocatalysts For Photocataly...mentioning

confidence: 99%

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Transition‐Metal‐Based Cocatalysts for Photocatalytic Water Splitting

et al. 2022

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Recently, semiconductor‐based photocatalytic water splitting has been extensively studied as a promising strategy for converting solar energy into carbon‐neutral and clean H2 fuel. However, the lack of sufficient active sites for surface redox reactions generally results in unsatisfactory photocatalytic water splitting performances over semiconductors. For this problem, cocatalyst provides an encouraging solution and is of great significance in improving photocatalytic performance. Noble metals and their derivatives are mostly utilized as efficient cocatalytic components, but their scarcity and expensiveness severely hamper large‐scale applications. Thereby, the utilization of noble‐metal‐free cocatalysts has aroused immense research attention. Owing to the facile availability, low cost, large abundance, high stability, and efficient performance, transition‐metal‐based materials have been developed as desirable candidates in the photocatalytic water splitting water splitting process. This review gives an outline of some recent advances in the active transition‐metal‐based water splitting cocatalysts. First, the fundamentals of transition‐metal‐based cocatalysts are presented, including the classification, function mechanisms, loading methods, modification strategies, and design considerations. Second, the various cases of depositing reduction cocatalysts, oxidation cocatalysts, and reduction–oxidation dual cocatalysts for water splitting are further discussed. Finally, the crucial challenges and possible research directions of transition‐metal‐based cocatalysts for photocatalytic water splitting are proposed.

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“…are inclined to capture holes, while reduction cocatalysts, containing Ag, Au, Pt, etc., exhibit appetency for electrons. At the same time, the existence of cocatalysts is conducive to accelerate the spatial reaction for the redox process. − Therefore, different cocatalysts can be reasonably designed to achieve the purposes of oxidation and reduction, respectively. Chung et al adopted a hydrothermal method to synthesize Pt-containing TiO 2 samples that demonstrated excellent hydrogen production performance and stability, and Liu and co-workers deposited CoFe-H on BiVO 4 photoanodes which displayed markedly heightened OER kinetics and photocurrent density .…”

Section: Introductionmentioning

confidence: 99%

Cu/CdS/MnO_x Nanostructure-Based Photocatalyst for Photocatalytic Hydrogen Evolution

Xiang

Hao

Jin

2021

ACS Appl. Nano Mater.

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Using cocatalysts to improve photocatalytic performance has become a common strategy. Dual cocatalysts deposited on semiconductors can effectively restrain charge recombination and counterreaction whereas cocatalysts would not be deposited on a position as anticipated in most situations, so that their roles would not be fully exploited to the fullest. Herein a Cu/CdS/MnO x (CSM) heterostructured photocatalyst was designed that not only exhibits excellent photocatalytic performance and stability but also achieves spatial separation of the photocarrier by the cocatalysts. As a reduction cocatalyst, Cu NPs tend to capture electrons, while as an oxidation cocatalyst, MnO x NPs prefer to collect holes. A hexagonal CdS crystal, with characteristics of different electron-rich and hole-rich facets, can direct the Cu NPs and MnO x NPs to deposit selectively on the corresponding facets without mixing. The unique structural features of the photocatalyst greatly suppress the recombination of photoinduced electrons and holes, facilitating the separation and transport of charges. The prolonged lifetime of photogenerated carriers and accelerated surface-reactive kinetics can be confirmed by time-resolved fluorescence spectra (TRPL) and photoelectrochemical characterization. The optimized 1% CSM photocatalyst shows a maximum H2 evolution rate of 5965.03 μmol h–1 g–1, which is about 5.3-fold that of neat CdS. This work provides dual cocatalysts with great potential to modify the photocatalytic activity of semiconductors for better applications.

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Sunlight Selective Photodeposition of CoO_x(OH)_y and NiO_x(OH)_y on Truncated Bipyramidal BiVO₄ for Highly Efficient Photocatalysis

Cited by 20 publications

References 78 publications

Unveiling Carrier Dynamics in Periodic Porous BiVO₄ Photocatalyst for Enhanced Solar Water Splitting

Unveiling Carrier Dynamics in Periodic Porous BiVO₄ Photocatalyst for Enhanced Solar Water Splitting

Transition‐Metal‐Based Cocatalysts for Photocatalytic Water Splitting

Cu/CdS/MnO_x Nanostructure-Based Photocatalyst for Photocatalytic Hydrogen Evolution

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Sunlight Selective Photodeposition of CoOx(OH)y and NiOx(OH)y on Truncated Bipyramidal BiVO4 for Highly Efficient Photocatalysis

Cited by 20 publications

References 78 publications

Unveiling Carrier Dynamics in Periodic Porous BiVO4 Photocatalyst for Enhanced Solar Water Splitting

Unveiling Carrier Dynamics in Periodic Porous BiVO4 Photocatalyst for Enhanced Solar Water Splitting

Transition‐Metal‐Based Cocatalysts for Photocatalytic Water Splitting

Cu/CdS/MnOx Nanostructure-Based Photocatalyst for Photocatalytic Hydrogen Evolution

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Product

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Sunlight Selective Photodeposition of CoO_x(OH)_y and NiO_x(OH)_y on Truncated Bipyramidal BiVO₄ for Highly Efficient Photocatalysis

Unveiling Carrier Dynamics in Periodic Porous BiVO₄ Photocatalyst for Enhanced Solar Water Splitting

Unveiling Carrier Dynamics in Periodic Porous BiVO₄ Photocatalyst for Enhanced Solar Water Splitting

Cu/CdS/MnO_x Nanostructure-Based Photocatalyst for Photocatalytic Hydrogen Evolution