Visible Light Water Splitting Using Dye-Sensitized Oxide Semiconductors

Youngblood, W. Justin; Lee, Seung Hyun Anna; Maeda, Kazuhiko; Mallouk, Thomas E.

doi:10.1021/ar9002398

Cited by 966 publications

(681 citation statements)

References 69 publications

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“…Nevertheless, photochemical conversion of solar power into electrical power is now possible using PV cells and photoelectrochemical (PEC) cells. [130][131][132][133] PV cells capture photons by exciting electrons across the band gap of a semiconductor. This process generates electron-hole pairs that are separated subsequently, typically by p-n junctions introduced by doping.…”

Section: Future Trendsmentioning

confidence: 99%

Hydrogen production by alkaline water electrolysis

Santos¹,

Sequeira²,

Figueiredo³

2013

Quím. Nova

389

226

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Recebido em 13/12/12; aceito em 28/5/13; publicado na web em 17/7/13Water electrolysis is one of the simplest methods used for hydrogen production. It has the advantage of being able to produce hydrogen using only renewable energy. To expand the use of water electrolysis, it is mandatory to reduce energy consumption, cost, and maintenance of current electrolyzers, and, on the other hand, to increase their efficiency, durability, and safety. In this study, modern technologies for hydrogen production by water electrolysis have been investigated. In this article, the electrochemical fundamentals of alkaline water electrolysis are explained and the main process constraints (e.g., electrical, reaction, and transport) are analyzed. The historical background of water electrolysis is described, different technologies are compared, and main research needs for the development of water electrolysis technologies are discussed.

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Section: Future Trendsmentioning

confidence: 99%

Hydrogen production by alkaline water electrolysis

Santos¹,

Sequeira²,

Figueiredo³

2013

Quím. Nova

389

226

View full text Add to dashboard Cite

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“…I n pursuit of sustainable energy systems such as solar fuels, much effort has been spent on water splitting to hydrogen and oxygen since hydrogen is a potential clean energy carrier and water is an abundant and environmentally benign resource (1)(2)(3)(4)(5). Water splitting consists of two half reactions: (i) water oxidation {H 2 O → 1∕2O 2 þ 2H þ þ 2e − [E ¼ 1.23-0.059 × pH V vs. normal hydrogen electrode (NHE)]} and (ii) proton reduction [2H þ þ 2e − → H 2 (E ¼ −0.059 × pH V vs. NHE)].…”

mentioning

confidence: 99%

“…To address this question, we have carried out calculations of the Gibbs free energy of the ligand exchange reactions (hydroxylation) for a number of ligands, including 4-picoline, isoquinoline, pyrimidine, This article is a PNAS Direct Submission. 1 Present address: Department of Chemistry, Yale University, New Haven, CT 06520. 2 To whom correspondence may be addressed.…”

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confidence: 99%

Highly efficient and robust molecular ruthenium catalysts for water oxidation

Duan

Araújo

Ahlquist

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

216

199

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Water oxidation catalysts are essential components of light-driven water splitting systems, which could convert water to H 2 driven by solar radiation (H 2 O þ hν → 1∕2O 2 þ H 2 ). The oxidation of water (H 2 O → 1∕2O 2 þ 2H þ þ 2e − ) provides protons and electrons for the production of dihydrogen (2H þ þ 2e − → H 2 ), a clean-burning and high-capacity energy carrier. One of the obstacles now is the lack of effective and robust water oxidation catalysts. Aiming at developing robust molecular Ru-bda (H 2 bda ¼ 2,2 0 -bipyridine-6,6′-dicarboxylic acid) water oxidation catalysts, we carried out density functional theory studies, correlated the robustness of catalysts against hydration with the highest occupied molecular orbital levels of a set of ligands, and successfully directed the synthesis of robust Ru-bda water oxidation catalysts. A series of mononuclear ruthenium complexes ½RuðbdaÞL 2 (L ¼ pyridazine, pyrimidine, and phthalazine) were subsequently synthesized and shown to effectively catalyze Ce IV -driven ½Ce IV ¼ CeðNH 4 Þ 2 ðNO 3 Þ 6 water oxidation with high oxygen production rates up to 286 s −1 and high turnover numbers up to 55,400.catalysis | density function theory | seven coordination | photosystem II | solar fuels I n pursuit of sustainable energy systems such as solar fuels, much effort has been spent on water splitting to hydrogen and oxygen since hydrogen is a potential clean energy carrier and water is an abundant and environmentally benign resource (1-5). Water splitting consists of two half reactions: (i) water oxidationIn practice, an overpotential is always present, leading to an even higher applied potential. The former half reaction requires strongly oxidizing conditions and is generally considered as the bottleneck of the whole water-splitting process due to the multiple protonelectron transfers and the formation of the O─O bond. Over the last few years, there has been an increasing development of water oxidation catalysts (WOCs) and many transition metal-based catalysts, including Ru (4, 5), Ir (6-8), Co (9-13), Fe (14,15), and Mn (16-18), have been reported with oxygen production rates (OPRs: mole oxygen produced per mole catalyst per second) ≤5 s −1 . Very recently, we reported a family of highly active Ru-based WOCs ½RuðbdaÞL 2 (H 2 L ¼ 2;2 -bipyridine-6,6′-dicarboxylic acid; L ¼ 4-picoline, A; L ¼ isoquinoline, B) ( Fig. 1) with OPRs up to 300 s −1 (19, 20); a seven-coordinate dimeric Ru IV intermediate (D7Ru IV ) (Fig. 1) is involved in the O─O bond formation step (20,21).A general problem encountered in molecular WOCs is the decomposition of catalysts. Ligand dissociation and oxidative decomposition have been considered as the major deactivation pathways. The groups of Llobet, Meyer, and Sun have demonstrated an improved durability of their catalysts by immobilizing catalysts on the electrode/material surface and thereby dramatically suppressing the intermolecular oxidative decomposition pathway (22-25).For our Ru-bda catalysts, the main deactivation pathway has been found to b...

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“…On the other hand, in the case of the O 2 formation reaction from AgNO 3 aqueous solution, almost the same formation rates were observed with the exception of that for PtO x /Zn-TPPD. These results suggest that the reduction and oxidation reaction sites of the PtO x /Zn-TPPD/ON-14 photocatalyst are the Pt co-catalyst and ON-14 surface, respectively, unlike the case for general dye-sensitized photocatalysts [29,30]. Although the PtO x /Zn-TPPD/ON-14 photocatalyst could form H 2 and O 2 from sacrificial reagent solutions, complete photocatalytic water splitting did not proceed on this photocatalyst.…”

Section: Resultsmentioning

confidence: 88%

Dye Modification Effects on TaON for Photocatalytic Hydrogen Production from Water

Hagiwara

Nagatomo

Seto³

et al. 2013

Catalysts

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Modification effects of porphyrin dyes on the photocatalytic activity of tantalum (oxy)nitride (TaON) were investigated. The nitrogen content in tantalum (oxy)nitride was increased by increasing the heat treatment period. The optimized nitridation conditions were found to be calcination at 800 °C for 14 h under a NH 3 gas flow (25 mL min −1). Among the porphyrin dyes examined, pentamethylene bis [4-(10,15,20-triphenylporphine-5-yl) benzoate]-dizinc (II) (Zn-TPPD) showed the most positive effect on the photocatalytic activity of TaON for H 2 production from Na 2 S aqueous solution. From the results of the photocatalytic reaction using various combinations of catalyst components, it was found that the modification dye and PtO x co-catalysts were necessary to achieving photocatalytic H 2 formation. In the PtO x /Zn-TPPD/TaON photocatalyst, the expected charge transfer mechanism was a two-step excitation of both TaON and Zn-TPPD, and the oxidation and reduction sites were TaON and PtO x co-catalyst, respectively. These results indicate that dye modification has the potential to improve the photocatalytic activity of various (oxy)nitride photocatalysts.

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Visible Light Water Splitting Using Dye-Sensitized Oxide Semiconductors

Cited by 966 publications

References 69 publications

Hydrogen production by alkaline water electrolysis

Hydrogen production by alkaline water electrolysis

Highly efficient and robust molecular ruthenium catalysts for water oxidation

Dye Modification Effects on TaON for Photocatalytic Hydrogen Production from Water

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