Visible Light Induced Hole Transport from Sensitizer to Co<sub>3</sub>O<sub>4</sub> Water Oxidation Catalyst across Nanoscale Silica Barrier with Embedded Molecular Wires

Agiral, A.; Soo, Han Sen; Frei, Heinz

doi:10.1021/cm400759f

Cited by 64 publications

(113 citation statements)

References 44 publications

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“…For example, photodriven proton reduction on the HER particle has to be much more selective than reduction of the redox mediator, despite the fact that reduction of the redox mediator is often much more thermodynamically favorable. Therefore, strategies that involve the selective transport of protons and H 2 through porous oxides [70] or composite shells [71] have been employed to minimize the reduction of O 2 at the catalyst surface. Other challenges include large distances for transport of the redox mediator in the solution and the membrane electrolyte, pH gradients between the two reactor vessels, and uncertain dimensions for the reactor construct; there is still a need for significant modeling and simulation studies as well as experimental validation to optimize these device designs.…”

Section: Particulate Designsmentioning

confidence: 99%

Modeling, Simulation, and Implementation of Solar‐Driven Water‐Splitting Devices

et al. 2016

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An integrated cell for the solar‐driven splitting of water consists of multiple functional components and couples various photoelectrochemical (PEC) processes at different length and time scales. The overall solar‐to‐hydrogen (STH) conversion efficiency of such a system depends on the performance and materials properties of the individual components as well as on the component integration, overall device architecture, and system operating conditions. This Review focuses on the modeling‐ and simulation‐guided development and implementation of solar‐driven water‐splitting prototypes from a holistic viewpoint that explores the various interplays between the components. The underlying physics and interactions at the cell level is are reviewed and discussed, followed by an overview of the use of the cell model to provide target properties of materials and guide the design of a range of traditional and unique device architectures.

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Section: Particulate Designsmentioning

confidence: 99%

Modeling, Simulation, and Implementation of Solar‐Driven Water‐Splitting Devices

et al. 2016

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“…[1][2][3][4][5][6][7][8][9][10][11] Understanding the catalysis mechanism is vital for the design of new functional materials to be a part of an environmentally friendly technology. The catalytic process on the surface of a semiconductor has been proposed by Izumi et al 12 and Matthews.…”

Section: Introductionmentioning

confidence: 99%

Selective isolation of the electron or hole in photocatalysis: ZnO–TiO2 and TiO2–ZnO core–shell structured heterojunction nanofibers via electrospinning and atomic layer deposition

et al. 2014

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Heterojunctions are a well-studied material combination in photocatalysis studies, the majority of which aim to improve the efficacy of the catalysts. Developing novel catalysts begs the question of which photo-generated charge carrier is more efficient in the process of catalysis and the associated mechanism. To address this issue we have fabricated core-shell heterojunction (CSHJ) nanofibers from ZnO and TiO 2 in two combinations where only the 'shell' part of the heterojunction is exposed to the environment to participate in the photocatalysis. Core and shell structures were fabricated via electrospinning and atomic layer deposition, respectively which were then subjected to calcination. These CSHJs were characterized and studied for photocatalytic activity (PCA). These two combinations expose electrons or holes selectively to the environment. Under suitable illumination of the ZnO-TiO 2 CSHJ, e/h pairs are created mainly in TiO 2 and the electrons take part in catalysis (i.e. reduce the organic dye) at the conduction band or oxygen vacancy sites of the 'shell', while holes migrate to the core of the structure. Conversely, holes take part in catalysis and electrons diffuse to the core in the case of a TiO 2 -ZnO CSHJ. The results further revealed that the TiO 2 -ZnO CSHJ shows $1.6 times faster PCA when compared to the ZnO-TiO 2 CSHJ because of efficient hole capture by oxygen vacancies, and the lower mobility of holes.

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“…[11][12][13][14] At room temperature, the most stable form of cobalt oxide is Co 3 O 4 , a semiconductor with a modest band gap of less than 1.6 eV, as compared to the 2.4 eV gap of charge-transfer insulator CoO. [15][16][17][18][19][20] Co 3 O 4 assumes the cubic Fd3m spinel-type phase, shown in Fig.…”

Section: Introductionmentioning

confidence: 99%

Epitaxy of polar semiconductor Co3O4 (110): Growth, structure, and characterization

Kormondy

Posadas

Slepko

et al. 2014

Journal of Applied Physics

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Articles you may be interested inMagnetic and structural properties of BiFeO3 thin films grown epitaxially on SrTiO3/Si substrates J. Appl. Phys. 113, 17D919 (2013) The (110) plane of Co 3 O 4 spinel exhibits significantly higher rates of carbon monoxide conversion due to the presence of active Co 3þ species at the surface. However, experimental studies of Co 3 O 4 (110) surfaces and interfaces have been limited by the difficulties in growing high-quality films. We report thin (10-250 Å ) Co 3 O 4 films grown by molecular beam epitaxy in the polar (110) direction on MgAl 2 O 4 substrates. Reflection high-energy electron diffraction, atomic force microscopy, x-ray diffraction, and transmission electron microscopy measurements attest to the high quality of the as-grown films. Furthermore, we investigate the electronic structure of this material by core level and valence band x-ray photoelectron spectroscopy, and first-principles density functional theory calculations. Ellipsometry reveals a direct band gap of 0.75 eV and other interband transitions at higher energies. A valence band offset of 3.2 eV is measured for the Co 3 O 4 /MgAl 2 O 4 heterostructure. Magnetic measurements show the signature of antiferromagnetic ordering at 49 K. FTIR ellipsometry finds three infrared-active phonons between 300 and 700 cm À1

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Visible Light Induced Hole Transport from Sensitizer to Co₃O₄ Water Oxidation Catalyst across Nanoscale Silica Barrier with Embedded Molecular Wires

Cited by 64 publications

References 44 publications

Modeling, Simulation, and Implementation of Solar‐Driven Water‐Splitting Devices

Modeling, Simulation, and Implementation of Solar‐Driven Water‐Splitting Devices

Selective isolation of the electron or hole in photocatalysis: ZnO–TiO2 and TiO2–ZnO core–shell structured heterojunction nanofibers via electrospinning and atomic layer deposition

Epitaxy of polar semiconductor Co3O4 (110): Growth, structure, and characterization

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Visible Light Induced Hole Transport from Sensitizer to Co3O4 Water Oxidation Catalyst across Nanoscale Silica Barrier with Embedded Molecular Wires

Cited by 64 publications

References 44 publications

Modeling, Simulation, and Implementation of Solar‐Driven Water‐Splitting Devices

Modeling, Simulation, and Implementation of Solar‐Driven Water‐Splitting Devices

Selective isolation of the electron or hole in photocatalysis: ZnO–TiO2 and TiO2–ZnO core–shell structured heterojunction nanofibers via electrospinning and atomic layer deposition

Epitaxy of polar semiconductor Co3O4 (110): Growth, structure, and characterization

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Visible Light Induced Hole Transport from Sensitizer to Co₃O₄ Water Oxidation Catalyst across Nanoscale Silica Barrier with Embedded Molecular Wires