Strategies for stable water splitting via protected photoelectrodes

Bae, Dowon; Seger, Brian; Vesborg, Peter Christian Kjærgaard; Hansen, Ole

doi:10.1039/c6cs00918b

Cited by 443 publications

(451 citation statements)

References 165 publications

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“…To be used, the metal, e.g. Ti, should have lower work function compared with the conduction band edge potential of the light harvester (figure 8) [22,53,85]. For example a thin layer of Ti metal, 5 nm in thickness, successfully protected and activated a p-Si photocathode [53].…”

Section: Via Improving Chemical and Photochemical Stabilitymentioning

confidence: 99%

“…In this article, we review the current trenches being developed in engineering of viable hybrid photocathodes for the hydrogen generation. The current development of photoanodes could be referred to several articles published elsewhere [7,[19][20][21][22][23]. We first describe the principal operation of a hybrid photocathode composed of a light harvester and a H 2 -evolving catalyst.…”

Section: Introductionmentioning

confidence: 99%

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Current perspectives in engineering of viable hybrid photocathodes for solar hydrogen generation

Thuy

et al. 2018

Adv. Nat. Sci: Nanosci. Nanotechnol.

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Photoelectrochemical water splitting represents an attractive technological solution to harvest and then store the solar energy which is abundant but intermittent. It can be achieved by employing a photoelectrochemical cell, also called an artificial leaf. In order to construct viable photoeclectrochemical cells, efforts are being dedicated to engineer robust and efficient photocathodes for solar H 2 generation and photoanodes for solar water oxidation reaction. In this article, we discuss on the recent achievements and current perspectives in engineering of viable hybrid photocathodes. The state of the art on the design of a hybrid photocathode, its performance as well as the current understanding of its mechanistic operation will be first described. We then discuss on the technical strategies that are currently being developed to enhance the robustness and performance of a hybrid photocathode.

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Section: Via Improving Chemical and Photochemical Stabilitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Current perspectives in engineering of viable hybrid photocathodes for solar hydrogen generation

Thuy

et al. 2018

Adv. Nat. Sci: Nanosci. Nanotechnol.

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“…The illustration in Figure 9 shows a photocatalyst particulate and the four basic steps, where (d) also includes the competing volume and surface recombination processes. An efficient photocatalyst must have band gap energies capable of the absorption of visible light energies and possess energetic band positions suitable for driving water reduction and oxidation reactions (i.e., E g ≥ 1.23 eV) [90]. The valence and conduction band energies of several semiconductors are plotted in Figure 10, and shown relative to the water redox couples for water splitting.…”

Section: Introductionmentioning

confidence: 99%

“…In addition perovskite-based photocatalysts have been extensively studied and various strategies have been employed for enhancing photocatalytic performance [90,114,115]. The use of mixed-metal compositions is critical to lowering the bandgap sizes of simpler metal oxides into the visible region [116].…”

Section: Introductionmentioning

confidence: 99%

Polymorphism and Structural Distortions of Mixed-Metal Oxide Photocatalysts Constructed with α-U3O8 Types of Layers

et al. 2017

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Abstract:A series of mixed-metal oxide structures based on the stacking of α-U 3 O 8 type pentagonal bipyramid layers have been investigated for symmetry lowering distortions and photocatalytic activity. The family of structures contains the general composition A m+ ((n+1)/m) B (3n+1) O (8n+3) (e.g., A = Ag, Bi, Ca, Cu, Ce, Dy, Eu, Gd K, La, Nd, Pb, Pr, Sr, Y; B = Nb, Ta; m = 1-3; n = 1, 1.5, 2), and the edge-shared BO 7 pentagonal pyramid single, double, and/or triple layers are differentiated by the average thickness, (i.e., 1 ≤ n ≤ 2), of the BO 7 layers and the local coordination environment of the "A" site cations. Temperature dependent polymorphism has been investigated for structures containing single layered (n = 1) monovalent (m = 1) "A" site cations (e.g., Ag 2 Nb 4 O 11 , Na 2 Nb 4 O 11 , and Cu 2 Ta 4 O 11 ). Furthermore, symmetry lowering distortions were observed for the Pb ion-exchange synthesis of Ag 2 Ta 4 O 11 to yield PbTa 4 O 11 . Several members within the subset of the family have been constructed with optical and electronic properties that are suitable for the conversion of solar energy to chemical fuels via water splitting.

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“…[9,10] Water is also needed to produce hydrogen as a clean and sustainable alternative energy source to fossil fuels by water splitting to prevent global warming stemmingf rom large-scale CO 2 emissions from the combustion of fossil fuels. [11][12][13][14][15][16][17][18][19][20] Therefore, water and clean energy are inextricably linked with each other.A bout 97 %o ft he water on our planet is seawater (3.0-5.0 %s alts) with 1.0 %b eing brackish ground water (0.05-3.0 %s alts), indicatingt hat the vast amounts of seawater would provide an early unlimited water supply if saline water could be used directly as ac lean and nearly infinite energy source. Microorganisms living in seawater can also be used in sediment microbial fuel cells to generate electric power from variouss ubstrates (electron sources) containing in seawater,w hich reduce dioxygen to water.…”

Section: Introductionmentioning

confidence: 99%

Fuel Production from Seawater and Fuel Cells Using Seawater

2017

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Seawater is the most abundant resource on our planet and fuel production from seawater has the notable advantage that it would not compete with growing demands for pure water. This Review focuses on the production of fuels from seawater and their direct use in fuel cells. Electrolysis of seawater under appropriate conditions affords hydrogen and dioxygen with 100 % faradaic efficiency without oxidation of chloride. Photoelectrocatalytic production of hydrogen from seawater provides a promising way to produce hydrogen with low cost and high efficiency. Microbial solar cells (MSCs) that use biofilms produced in seawater can generate electricity from sunlight without additional fuel because the products of photosynthesis can be utilized as electrode reactants, whereas the electrode products can be utilized as photosynthetic reactants. Another important source for hydrogen is hydrogen sulfide, which is abundantly found in Black Sea deep water. Hydrogen produced by electrolysis of Black Sea deep water can also be used in hydrogen fuel cells. Production of a fuel and its direct use in a fuel cell has been made possible for the first time by a combination of photocatalytic production of hydrogen peroxide from seawater and dioxygen in the air and its direct use in one‐compartment hydrogen peroxide fuel cells to obtain electric power.

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Strategies for stable water splitting via protected photoelectrodes

Cited by 443 publications

References 165 publications

Current perspectives in engineering of viable hybrid photocathodes for solar hydrogen generation

Current perspectives in engineering of viable hybrid photocathodes for solar hydrogen generation

Polymorphism and Structural Distortions of Mixed-Metal Oxide Photocatalysts Constructed with α-U3O8 Types of Layers

Fuel Production from Seawater and Fuel Cells Using Seawater

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