Efficient Water Splitting Cascade Photoanodes with Ligand‐Engineered MnO Cocatalysts

Lee, Mi Gyoung; Jin, Kyoungsuk; Kwon, Ki Chang; Sohn, Woonbae; Park, Hoonkee; Choi, Kyoung Soon; Go, Yoo Kyung; Seo, Hongmin; Hong, Jung Sug; Nam, Ki Tae; Jang, Ho Won

doi:10.1002/advs.201800727

Cited by 31 publications

(26 citation statements)

References 77 publications

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“…Recently, substantial research have been conducted on developing earth‐abundant element based electrocatalysts with high activity, selectivity, and long‐term stability. Transition metals and their compounds, such as transition metal oxides, hydroxides, chalcogenides, phosphides, carbides, and borides, have been intensively investigated as a substitute of noble metal catalysts. Albeit tremendous effort and attention, the performance of these electrocatalysts for energy conversion is still unsatisfactory compared to noble‐metal–catalysts.…”

Section: Introductionmentioning

confidence: 99%

Reduced graphene oxide‐based materials for electrochemical energy conversion reactions

et al. 2019

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There have been ever-growing demands to develop advanced electrocatalysts for renewable energy conversion over the past decade. As a promising platform for advanced electrocatalysts, reduced graphene oxide (rGO) has attracted substantial research interests in a variety of electrochemical energy conversion reactions. Its versatile utility is mainly attributed to unique physical and chemical properties, such as high specific surface area, tunable electronic structure, and the feasibility of structural modification and functionalization. Here, a comprehensive discussion is provided upon recent advances in the material preparation, characterization, and the catalytic activity of rGO-based electrocatalysts for various electrochemical energy conversion reactions (water splitting, CO 2 reduction reaction, N 2 reduction reaction, and O 2 reduction reaction). Major advantages of rGO and the related challenges for enhancing their catalytic performance are addressed. K E Y W O R D S

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Section: Introductionmentioning

confidence: 99%

Reduced graphene oxide‐based materials for electrochemical energy conversion reactions

et al. 2019

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“…BiVO 4 was electrodeposited onto the two types of TiO 2 nanostructures using previously reported methods [ 5 , 23 ]. A precursor was prepared by dissolving bismuth nitrate pentahydrate (BiN 3 O 9 , 98%, Junsei) in a solution of vanadium oxide sulfate hydrate (VOSO 4 , 99.99%, Aldrich) at pH < 0.5 with nitric acid (HNO 3 , 67%, Junsei).…”

Section: Methodsmentioning

confidence: 99%

Crystal Facet Engineering of TiO2 Nanostructures for Enhancing Photoelectrochemical Water Splitting with BiVO4 Nanodots

et al. 2022

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Although bismuth vanadate (BiVO4) has been promising as photoanode material for photoelectrochemical water splitting, its charge recombination issue by short charge diffusion length has led to various studies about heterostructure photoanodes. As a hole blocking layer of BiVO4, titanium dioxide (TiO2) has been considered unsuitable because of its relatively positive valence band edge and low electrical conductivity. Herein, a crystal facet engineering of TiO2 nanostructures is proposed to control band structures for the hole blocking layer of BiVO4 nanodots. We design two types of TiO2 nanostructures, which are nanorods (NRs) and nanoflowers (NFs) with different (001) and (110) crystal facets, respectively, and fabricate BiVO4/TiO2 heterostructure photoanodes. The BiVO4/TiO2 NFs showed 4.8 times higher photocurrent density than the BiVO4/TiO2 NRs. Transient decay time analysis and time-resolved photoluminescence reveal the enhancement is attributed to the reduced charge recombination, which is originated from the formation of type II band alignment between BiVO4 nanodots and TiO2 NFs. This work provides not only new insights into the interplay between crystal facets and band structures but also important steps for the design of highly efficient photoelectrodes.

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“…In addition, the metal oxide MnO catalysts on BiVO 4 /WO 3 functionalized with BF 4 − oxidizes water molecules under neutral condition, showed the enhanced catalytic performance. This result is due to the band edge modulation created by ligand functionalization on the surface [80]. The barrier height at the solid-liquid interface, which is measured as open-circuit voltage, can be controlled by the surface functionalities [73,81].…”

Section: Surface Functionalization At the Solid-liquid Interface For mentioning

confidence: 99%

Understanding Surface Modulation to Improve the Photo/Electrocatalysts for Water Oxidation/Reduction

Cho

Lee

2020

Molecules

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Water oxidation and reduction reactions play vital roles in highly efficient hydrogen production conducted by an electrolyzer, in which the enhanced efficiency of the system is apparently accompanied by the development of active electrocatalysts. Solar energy, a sustainable and clean energy source, can supply the kinetic energy to increase the rates of catalytic reactions. In this regard, understanding of the underlying fundamental mechanisms of the photo/electrochemical process is critical for future development. Combining light-absorbing materials with catalysts has become essential to maximizing the efficiency of hydrogen production. To fabricate an efficient absorber-catalysts system, it is imperative to fully understand the vital role of surface/interface modulation for enhanced charge transfer/separation and catalytic activity for a specific reaction. The electronic and chemical structures at the interface are directly correlated to charge carrier movements and subsequent chemical adsorption and reaction of the reactants. Therefore, rational surface modulation can indeed enhance the catalytic efficiency by preventing charge recombination and prompting transfer, increasing the reactant concentration, and ultimately boosting the catalytic reaction. Herein, the authors review recent progress on the surface modification of nanomaterials as photo/electrochemical catalysts for water reduction and oxidation, considering two successive photogenerated charge transfer/separation and catalytic chemical reactions. It is expected that this review paper will be helpful for the future development of photo/electrocatalysts.

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Efficient Water Splitting Cascade Photoanodes with Ligand‐Engineered MnO Cocatalysts

Cited by 31 publications

References 77 publications

Reduced graphene oxide‐based materials for electrochemical energy conversion reactions

Reduced graphene oxide‐based materials for electrochemical energy conversion reactions

Crystal Facet Engineering of TiO2 Nanostructures for Enhancing Photoelectrochemical Water Splitting with BiVO4 Nanodots

Understanding Surface Modulation to Improve the Photo/Electrocatalysts for Water Oxidation/Reduction

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