Unveiling the Activity and Stability Origin of BiVO<sub>4</sub> Photoanodes with FeNi Oxyhydroxides for Oxygen Evolution

Zhang, Beibei; Huang, Xiaojuan; Zhang, Yan; Lü, Gongxuan; Chou, Lingjun; Bi, Yingpu

doi:10.1002/anie.202008198

Cited by 144 publications

(131 citation statements)

References 39 publications

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“…[255] Through density functional theory calculations and experimental studies, it showed that the doping of Fe atoms into the lattice of CoO x produced abundant oxygen vacancies, which significantly improved the interfacial hole injection property of BiVO 4 and reduced the OER onset potential (Figure 19d). Recently, many other advanced co-catalysts have been demonstrated with outstanding performance and stability, such as natural polyphenols/Fe ion, [256] Cu porphyrin, [257] Fe-based (Ni 1−x Fe x and Co 1−x Fe x ) layered double hydroxide, [258][259][260][261] InPO x , [86] molecular Co Cubane, [262] MnO 2 , [263][264][265] and Co 8 -polyoxometalates. [266] In Table 4, it can be seen that by modifying pristine semiconductors with co-catalyst, boosted PEC performance can be achieved due to the significantly enhanced interfacial hole-injection efficiency.…”

Section: Co-catalyst Developmentmentioning

confidence: 99%

Engineering Nanostructure–Interface of Photoanode Materials Toward Photoelectrochemical Water Oxidation

et al. 2021

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In practical applications, solar energy is usually converted to other forms of energy, such as electric energy, [9][10][11] chemical energy, [12,13] thermal energy, [14,15] so as to facilitate further transportation and storage. Among them, photoelectrochemical (PEC) reactions from water to hydrogen, CO 2 to C2+ products, and N 2 to NH 3 in the aqueous-based environment have been considered to be quite promising solar-chemical energy conversion pathways. [16][17][18][19] Unlike the traditional water electrolyzing system, the most ideal PEC reaction system can be selfdriven by illumination without external bias. Utilizing the electron-hole carriers generated from the semiconductor photoelectrode, redox reactions take place separately on the photocathode and photoanode. However, as the water oxidation reaction involves a complex four-proton coupled multi-electron process (2H 2 O + 4h + → O 2 + 4H + , E o = 1.23 V vs reversible hydrogen electrode (RHE)), it makes the water oxidation reaction the rate-control step in the watersplitting reaction. [20] Therefore, developing high-performance photo anodes is of great fundamental importance and interest.At the present stage, TiO 2 is the most studied and applied semiconductor photoelectrocatalyst, due to its outstanding chemical stability. [21][22][23] However, as a wide bandgap semiconductor (anatase TiO 2 : 3.2eV, rutile TiO 2 : 3.0 eV), TiO 2 can only respond to the ultraviolet light. Meanwhile, as an intrinsic semiconductor, the bulk/surficial carrier recombination of TiO 2 greatly hinders its practical application. [24][25][26][27] In that case, some narrow bandgap semiconductors are also applied as the photoanode materials, such as Ta 3 N 5 (bandgap 2.1 eV), [28,29] BiVO 4 (bandgap 2.4 eV), and α-Fe 2 O 3 (bandgap 2.1 eV). [30][31][32] However, many of these narrow bandgap materials suffer from poor chemical stability and sluggish interfacial charge injection. [33][34][35] As intrinsic semiconductor materials, both wide and narrow bandgap semiconductor photoanode materials are suffering from the poor bulk-phase carrier separation, intense surficial e − /h + trapping recombination, and sluggish electrode/electrolyte carrier injection kinetics. [36][37][38][39] Fortunately, with the continuous investment of researchers, a series of modification methods have been established and the PEC water oxidation performance of semiconductor photoanode materials has been significantly improved. [32,[40][41][42][43][44] Among various strategies, nanostructure-interface engineering is widely regarded as an effective method to improve the PEC water oxidation performance: [40,41] the light-harvesting performance can be enhanced by the widened optical Photoelectrochemical (PEC) water oxidation based on semiconductor materials plays an important role in the production of clean fuel and value-added chemicals. Nanostructure-interface engineering has proven to be an effective way to construct highly efficient PEC water oxidation photoanodes with good light capture, carrier transport, and ...

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Section: Co-catalyst Developmentmentioning

confidence: 99%

Engineering Nanostructure–Interface of Photoanode Materials Toward Photoelectrochemical Water Oxidation

et al. 2021

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“…As can be seen in Figure S4, Supporting Information, BV film belongs to monoclinic structure (PDF#14-0688), [23] which is in accordance with previous reports. [18,22] The Raman peaks of BV are located at 210.0, 324.0, 366.0, 640.0, 710.0 and 826.0 cm −1 (Figure S5, Supporting Information), meaning that the BV films have been successfully synthesized. [24] Subsequently, the ultrathin amorphous Co(OH) 2 (Figure S6, Supporting Information) nanosheets were uniformly electrodeposited on BV photoanodes (named as BV/Co(OH) 2 ).…”

Section: Synthesis and Characterization Of The Bv/co(oh) X -Ag Photoanodesmentioning

confidence: 99%

“…From Figure S10b,c, Supporting Information, the Bi 4f and V 2P peaks are consistent with values reported previously. [18,22] The high-resolution Co 2p of BV/Co(OH) x -Ag can yield two spin-orbit doublets. The two peaks at 781.8 and 797.7 eV are generated by Co 2+ and another two peaks at 780.2 and 795.3 eV are ascribed to Co 3+ (Figure S11a, Supporting Information).…”

Section: Microscopy (Tem) From Figuresmentioning

confidence: 99%

Plasmon‐Enhanced Charge Separation and Surface Reactions Based on Ag‐Loaded Transition‐Metal Hydroxide for Photoelectrochemical Water Oxidation

Ning

Yin

Fan

et al. 2021

Advanced Energy Materials

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Coating photoanodes with transition‐metal hydroxides (TMH) is a promising approach for improving photoelectrochemical (PEC) water oxidation. However, the present system still suffers from high charge recombination and sluggish surface reactions. Herein, effective charge separation is achieved at the same time as boosting the surface catalytic reaction for PEC water splitting through decoration of plasmon metal (Ag) in a semiconductor/TMH coupling system. The kinetic behavior at the semiconductor/TMH and TMH/electrolyte interfaces is systematically evaluated by employing intensity modulated photocurrent spectroscopy, scanning photoelectrochemical microscopy, and oxygen evolution reaction model. It is found that both charge transfer and surface catalysis dynamics are enhanced through local surface plasmon resonance of Ag nanoparticles. The as‐prepared BiVO4/Co(OH)x‐Ag exhibits remarkable activity (≈4.64 times) in PEC water splitting in comparison with pure BiVO4. Notably, this smart approach can be also applied to other TMH (Ni(OH)2), reflecting its universality. This work provides a guiding design method for solar energy conversion with the semiconductor‐TMH system.

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“…[ 6,7 ] Cost‐competitive metal oxide semiconductors such as Cu 2 O, BiVO 4 , and Fe 2 O 3 are intriguing selections due to their high abundance and easy processability. [ 8–12 ] Nevertheless, oxide‐based photoelectrodes still exhibit low photocatalytic efficiency and poor stability in aqueous electrolytes, limiting their practical applications. [ 13–15 ]…”

Section: Introductionmentioning

confidence: 99%

Stable Unbiased Photo‐Electrochemical Overall Water Splitting Exceeding 3% Efficiency via Covalent Triazine Framework/Metal Oxide Hybrid Photoelectrodes

Zhang

et al. 2021

Advanced Materials

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Photo‐electrochemical (PEC) water splitting systems using oxide‐based photoelectrodes are highly attractive for solar‐to‐chemical energy conversion. However, despite decades‐long efforts, it is still challenging to develop efficient and stable photoelectrodes for practical applications. Here, thin layers of covalent triazine frameworks (CTF‐BTh) containing a bithiophene moiety are conformably deposited onto the surfaces of a Cu2O photocathode and a Mo‐doped BiVO4 photoanode via electropolymerization to construct new hybrid photoelectrodes, successfully addressing the efficiency and stability issues. The CTF‐BTh possesses a suitable band structure to form favorable band edge alignment with each metal oxide, creating a p–n junction and a staggered type‐II heterojunction with Cu2O and Mo‐doped BiVO4, respectively. Thus, the as‐fabricated hybrid photoelectrodes exhibit substantially increased PEC performances. Meanwhile, the CTF‐BTh film also serves as an effective corrosion‐resistant overlayer for both photoelectrodes to inhibit photocorrosion and enable long‐term operation for 150 h with only ≈10% loss in photocurrent densities. Furthermore, a stand‐alone unbiased PEC tandem device comprising CTF‐BTh‐coated photoelectrodes exhibits 3.70% solar‐to‐hydrogen conversion efficiency. Even after continuous operation for 120 h, the efficiency can still retain at 3.24%.

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Unveiling the Activity and Stability Origin of BiVO₄ Photoanodes with FeNi Oxyhydroxides for Oxygen Evolution

Cited by 144 publications

References 39 publications

Engineering Nanostructure–Interface of Photoanode Materials Toward Photoelectrochemical Water Oxidation

Engineering Nanostructure–Interface of Photoanode Materials Toward Photoelectrochemical Water Oxidation

Plasmon‐Enhanced Charge Separation and Surface Reactions Based on Ag‐Loaded Transition‐Metal Hydroxide for Photoelectrochemical Water Oxidation

Stable Unbiased Photo‐Electrochemical Overall Water Splitting Exceeding 3% Efficiency via Covalent Triazine Framework/Metal Oxide Hybrid Photoelectrodes

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Unveiling the Activity and Stability Origin of BiVO4 Photoanodes with FeNi Oxyhydroxides for Oxygen Evolution

Cited by 144 publications

References 39 publications

Engineering Nanostructure–Interface of Photoanode Materials Toward Photoelectrochemical Water Oxidation

Engineering Nanostructure–Interface of Photoanode Materials Toward Photoelectrochemical Water Oxidation

Plasmon‐Enhanced Charge Separation and Surface Reactions Based on Ag‐Loaded Transition‐Metal Hydroxide for Photoelectrochemical Water Oxidation

Stable Unbiased Photo‐Electrochemical Overall Water Splitting Exceeding 3% Efficiency via Covalent Triazine Framework/Metal Oxide Hybrid Photoelectrodes

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Unveiling the Activity and Stability Origin of BiVO₄ Photoanodes with FeNi Oxyhydroxides for Oxygen Evolution