A hole inversion layer at the BiVO4/Bi4V2O11 interface produces a high tunable photovoltage for water splitting

Santos, Wayler S. dos; Rodríguez, Mariandry; Afonso, André S.; Mesquita, João Paulo de; Nascimento, Lucas L.; Patrocínio, Antonio Otávio T.; Silva, Adilson C.; Oliveira, Luiz C.A.; Fabris, José Domingos; Pereira, Márcio C.

doi:10.1038/srep31406

Cited by 56 publications

(35 citation statements)

References 42 publications

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“…Notably, pristine FTO/BiVO 4 photoanodes (prepared under 0.1 mbar with removed V 2 O 5 ) generated a lower photocurrent than photoanodes consisting of the BiVO 4 @Bi 4 V 2 O 11 heterojunction. It has been already reported that such a system positively affects the photoelectroactivity in comparison to bare BiVO 4 [31,36]. The geometry of the system should be taken into account, as it was discussed for the BiVO 4 /V 2 O 5 photoanode.…”

Section: Resultsmentioning

confidence: 99%

“…The formation of heterojunction leads to the inhibition of bulk electron/hole recombination [38]. Generally, the presence of type-II heterojunction enhances bulk e − /h + separation efficiency due to the internal electric field generated on the phases interface, e.g., BiVO 4 /Bi 4 V 2 O 11 [36]. The enhancement of photoactivity in the case of the Bi 4 V 2 O 11 -containing photoanode may be also related to improved charge transfer resistance through the photoactive film in comparison with pristine BiVO 4 as it was reported previously [22].…”

Section: Resultsmentioning

confidence: 99%

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Pulsed Laser Deposition of Bismuth Vanadate Thin Films—The Effect of Oxygen Pressure on the Morphology, Composition, and Photoelectrochemical Performance

et al. 2020

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Thin layers of bismuth vanadate were deposited using the pulsed laser deposition technique on commercially available FTO (fluorine-doped tin oxide) substrates. Films were sputtered from a sintered, monoclinic BiVO4 pellet, acting as the target, under various oxygen pressures (from 0.1 to 2 mbar), while the laser beam was perpendicular to the target surface and parallel to the FTO substrate. The oxygen pressure strongly affects the morphology and the composition of films observed as a Bi:V ratio gradient along the layer deposited on the substrate. Despite BiVO4, two other phases were detected using XRD (X-ray diffraction) and Raman spectroscopy—V2O5 and Bi4V2O11. The V-rich region of the samples deposited under low and intermediate oxygen pressures was covered by V2O5 longitudinal structures protruding from BiVO4 film. Higher oxygen pressure leads to the formation of Bi4V2O11@BiVO4 bulk heterojunction. The presented results suggest that the ablation of the target leads to the plasma formation, where Bi and V containing ions can be spatially separated due to the interactions with oxygen molecules. In order to study the phenomenon more thoroughly, laser-induced breakdown spectroscopy measurements were performed. Then, obtained electrodes were used as photoanodes for photoelectrochemical water splitting. The highest photocurrent was achieved for films deposited under 1 mbar O2 pressure and reached 1 mA cm−2 at about 0.8 V vs Ag/AgCl (3 M KCl). It was shown that V2O5 on the top of BiVO4 decreases its photoactivity, while the presence of a bulk Bi4V2O11@BiVO4 heterojunction is beneficial in water photooxidation.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Pulsed Laser Deposition of Bismuth Vanadate Thin Films—The Effect of Oxygen Pressure on the Morphology, Composition, and Photoelectrochemical Performance

et al. 2020

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“…The illuminated open-circuit potential (OCP) is a feasible way for determining V fb when sufficient light is illuminated to remove band bending. This technique is an effective and convenient way to obtain the V ph of the electrode and gives useful information about the band bending and is commonly measured by increasing the light intensity until the J ph saturates [46]. Figure 7 depicts the OCP versus the illumination intensity to the samples of p-GaAsPN cell, MDMP-PPV:PCMB (bulk heterojunctions consisting of polyf2-methoxy-5-s38,78-dimethyloctyloxyd-pphenylenevinylene (MDMO-PPV) and 6,6-phenyl C61-butyric acid methyl ester PCBM), dye-sensitized solar cell (DSSC) (ITO/CuPc/C 60 /BPen/Al) and polycrystalline Si.…”

Section: Illuminated Open-circuit Potential (Ocp)mentioning

confidence: 99%

“…et al, who introduced an efficient approach which is coupling ferroelectric materials with semiconductors to boost the photovoltage higher than that obtainable from a conventional p-n heterojunction. The ferroelectric Bi 4 V 2 O 11 perovskite and n-type BiVO 4 creates a virtual p-n junction that produces high photovoltage of 1.39 V ( Figure 8j) [46]. The metal-insulator-semiconductor (MIS) photoanode using silicon was fabricated by Digdaya et al [57].…”

Section: Illuminated Open-circuit Potential (Ocp)mentioning

confidence: 99%

Metal Chalcogenides on Silicon Photocathodes for Efficient Water Splitting: A Mini Overview

et al. 2019

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In the photoelectrochemical (PEC) water splitting (WS) reactions, a photon is absorbed by a semiconductor, generating electron-hole pairs which are transferred across the semiconductor/electrolyte interface to reduce or oxidize water into oxygen or hydrogen. Catalytic junctions are commonly combined with semiconductor absorbers, providing electrochemically active sites for charge transfer across the interface and increasing the surface band bending to improve the PEC performance. In this review, we focus on transition metal (di)chalcogenide [TM(D)C] catalysts in conjunction with silicon photoelectrode as Earth-abundant materials systems. Surprisingly, there is a limited number of reports in Si/TM(D)C for PEC WS in the literature. We provide almost a complete survey on both layered TMDC and non-layered transition metal dichalcogenides (TMC) co-catalysts on Si photoelectrodes, mainly photocathodes. The mechanisms of the photovoltaic power conversion of silicon devices are summarized with emphasis on the exact role of catalysts. Diverse approaches to the improved PEC performance and the proposed synergetic functions of catalysts on the underlying Si are reviewed. Atomic layer deposition of TM(D)C materials as a new methodology for directly growing them and its implication for low-temperature growth on defect chemistry are featured. The multi-phase TM(D)C overlayers on Si and the operation principles are highlighted. Finally, challenges and directions regarding future research for achieving the theoretical PEC performance of Si-based photoelectrodes are provided.

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“…Nanostructures of Bi 2 WO 6 , [77] Bi 2 MoO 6 , [78] Bi 2 O 2 CO 3 , [79] BiOX (X = Cl, Br,I ), [80][81][82] Bi 2 S 3 [83] and BiVO 4 [84] were synthesized as photocatalysts to decompose organic pollutants under visible-light irradiation. Although various methods, such as composite photocatalysts, noble metal loading and interfacial electric field, were used to improve the photocatalytic efficiency of bismuth-based photocatalysts, [84][85][86] the materials still demonstrate low quantum yields leadingt o www.chemphotochem.org low photocatalytic efficiencies. Therefore, buildinga ni nternal electric field in the crystal structure of photocatalystsi sa ne fficient strategy to greatlyi mprove charges eparationt oo btain materials with ahighq uantum yield.…”

Section: Layer-structure Polar Photocatalystsmentioning

confidence: 99%

Enhancing Charge Separation in Photocatalysts with Internal Polar Electric Fields

et al. 2017

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The main limitations on photocatalytic efficiency are the recombination of photogenerated electrons and holes and a narrow light response. In this Minireview, we focused on photocatalytic materials with an internal polar electric field. The development and application of these compounds is one of the most efficient strategies to promote the separation of photogenerated electrons and holes, leading to high photocatalytic efficiency. This Minireview describes the fundamental operating principles of photocatalysts with a built‐in polar electric field and discusses the mechanism for polar‐electric‐field‐enhanced charge separation. We also review recent reports on photocatalytic systems using an internal polar electric field to separate photogenerated electrons and holes, focusing particularly on layer‐structure polar photocatalysts, silver silicates, and single‐crystal ZnO photocatalysts. Charge separation enhanced by an internal polar electric field provides the basis for designing new high efficiency photocatalysts.

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A hole inversion layer at the BiVO4/Bi4V2O11 interface produces a high tunable photovoltage for water splitting

Cited by 56 publications

References 42 publications

Pulsed Laser Deposition of Bismuth Vanadate Thin Films—The Effect of Oxygen Pressure on the Morphology, Composition, and Photoelectrochemical Performance

Pulsed Laser Deposition of Bismuth Vanadate Thin Films—The Effect of Oxygen Pressure on the Morphology, Composition, and Photoelectrochemical Performance

Metal Chalcogenides on Silicon Photocathodes for Efficient Water Splitting: A Mini Overview

Enhancing Charge Separation in Photocatalysts with Internal Polar Electric Fields

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