Photocatalytic Hydrogen Production Using Models of the Iron–Iron Hydrogenase Active Site Dispersed in Micellar Solution

Orain, Christophe; Quentel, François; Gloaguen, Frédéric

doi:10.1002/cssc.201300631

Cited by 62 publications

(69 citation statements)

References 63 publications

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“…[29] A higher efficiency of hydrogen production was achieveda t pH 11.0. This value is larger than the systems containing an iron-iron hydrogenaser edox catalyst with Fl as photosensitizer, [30] confirming the advantage of the supramolecular system for photocatalytic hydrogen production.C ontrol experiments revealed that the absence of any of these individual components resulted in no hydrogen production andt hat the artificial system did not functionw ell in the absence of light.T he reactions using the mononuclear tris(bipyridine)iron complex, which resembles the corner of the molecular cube as redox catalyst, produces only very small amounts (< 20 mLh ydrogen) under the same experimental conditions with same iron ion concentration. About 0.20 mL hydrogen productionw as achieved at ap Ho f1 1.0.…”

Section: Resultsmentioning

confidence: 92%

Redox‐Active M₈L₆ Cubic Hosts with Tetraphenylethylene Faces Encapsulate Organic Dyes for Light‐Driven H₂ Production

Yang

et al. 2016

Chemistry A European J

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The design of artificial systems that mimic highly evolved and finely tuned natural enzymes is a promising subject of intensive research. The assembly of O-symmetric cubic structures with an Fe L formula was reported through the direct combination of a C -symmetric tetraphenylethylene-based ligand with a C -symmetric tris(bipyridine)iron node. The robust metal-organic cubes are rich in π-electron density and provide favorable interactions with planar polycyclic aromatic hydrocarbons. Within the confined space of the host, the aromatic hydrocarbons molecules are forced closer to the redox active host, and the photoinduced electron transfer (PET) is modified into a pseudo-intramolecular pathway. These iron vertices within the cubes exhibit suitable redox potential for electrochemical reduction of protons and the well-modified PET is further tailored to create artificial systems for light-driven hydrogen evolution from water through the encapsulation of fluorescein dyes. Control experiments based on a mononuclear compound resembling the iron corner of the octahedron suggest an enzymatic dynamic behavior. The new, well-elucidated reaction pathways and the increased molarity of the reaction within the confined space render these supramolecular systems superior to other relevant systems.

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Section: Resultsmentioning

confidence: 92%

Redox‐Active M₈L₆ Cubic Hosts with Tetraphenylethylene Faces Encapsulate Organic Dyes for Light‐Driven H₂ Production

Yang

et al. 2016

Chemistry A European J

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“…Some of these homogeneous photocatalytic systems can operate very efficiently (in terms of number of catalytic cycles or turnover number (TON)) in organic or mixed aqueous-organic solvents. Those reaching a turnover number versus catalyst (TON Cat ) above 100 in fully aqueous solution were rare and limited to rhodium [36][37][38][39] and platinum [40] but, since two years, several examples with cobalt [41][42][43][44][45][46][47][48][49][50][51][52][53][54], iron [55][56][57][58] nickel [59] were reported. Developing H 2 -evolving photocatalytic systems functioning in pure water is essential for their coupling with water oxidation systems in photoelectrochemical water-splitting devices.…”

Section: Introductionmentioning

confidence: 98%

Photo-induced redox catalysis for proton reduction to hydrogen with homogeneous molecular systems using rhodium-based catalysts

Stoll

Castillo

Kayanuma

et al. 2015

Coordination Chemistry Reviews

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“…1 In this context, efficient photocatalytic production of dihydrogen (H 2 ) under visible-light irradiation, which is believed to be a convenient clean energy carrier for the future, is an important goal. [6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21] Those operating efficiently in fully aqueous solution were rare and limited to noble-metal based catalysts (rhodium and platinum) [22][23][24][25][26][27] until 2012, when several examples with cobalt, [28][29][30][31][32][33][34][35][36][37][38][39][40][41] iron [42][43][44][45] and nickel-based 46 catalysts were reported. Numerous photocatalytic systems in literature exhibit high activity in organic media or in mixtures of aqueous/organic solvents.…”

Section: Introductionmentioning

confidence: 99%

A computational mechanistic investigation of hydrogen production in water using the [Rh^III(dmbpy)₂Cl₂]⁺/[Ru^II(bpy)₃]²⁺/ascorbic acid photocatalytic system

Kayanuma

Stoll

Daniel

et al. 2015

Phys. Chem. Chem. Phys.

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We recently reported an efficient molecular homogeneous photocatalytic system for hydrogen (H2) production in water combining [Rh(III)(dmbpy)2Cl2](+) (dmbpy = 4,4'-dimethyl-2,2'-bipyridine) as a H2 evolving catalyst, [Ru(II)(bpy)3](2+) (bpy = 2,2'-bipyridine) as a photosensitizer and ascorbic acid as a sacrificial electron donor (Chem. - Eur. J., 2013, 19, 781). Herein, the possible rhodium intermediates and mechanistic pathways for H2 production with this system were investigated at DFT/B3LYP level of theory and the most probable reaction pathways were proposed. The calculations confirmed that the initial step of the mechanism is a reductive quenching of the excited state of the Ru photosensitizer by ascorbate, affording the reduced [Ru(II)(bpy)2(bpy˙(-))](+) form, which is capable, in turn, of reducing the Rh(III) catalyst to the distorted square planar [Rh(I)(dmbpy)2](+) species. This two-electron reduction by [Ru(II)(bpy)2(bpy˙(-))](+) is sequential and occurs according to an ECEC mechanism which involves the release of one chloride after each one-electron reduction step of the Rh catalyst. The mechanism of disproportionation of the intermediate Rh(II) species, much less thermodynamically favoured, cannot be barely ruled out since it could also be favoured from a kinetic point of view. The Rh(I) catalyst reacts with H3O(+) to generate the hexa-coordinated hydride [Rh(III)(H)(dmbpy)2(X)](n+) (X = Cl(-) or H2O), as the key intermediate for H2 release. The DFT study also revealed that the real source of protons for the hydride formation as well as the subsequent step of H2 evolution is H3O(+) rather than ascorbic acid, even if the latter does govern the pH of the aqueous solution. Besides, the calculations have shown that H2 is preferentially released through an heterolytic mechanism by reaction of the Rh(III)(H) hydride and H3O(+); the homolytic pathway, involving the reaction of two Rh(III)(H) hydrides, being clearly less favoured. In parallel to this mechanism, the reduction of the Rh(III)(H) hydride into the penta-coordinated species [Rh(II)(H)(dmbpy)2](+) by [Ru(II)(bpy)2(bpy˙(-))](+) is also possible, according to the potentials of the respective species determined experimentally and this is confirmed by the calculations. From this Rh(II)(H) species, the heterolytic and homolytic pathways are both thermodynamically favourable to produce H2 confirming that Rh(II)(H) is as reactive as Rh(III)(H) towards the production of H2.

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Photocatalytic Hydrogen Production Using Models of the Iron–Iron Hydrogenase Active Site Dispersed in Micellar Solution

Cited by 62 publications

References 63 publications

Redox‐Active M₈L₆ Cubic Hosts with Tetraphenylethylene Faces Encapsulate Organic Dyes for Light‐Driven H₂ Production

Redox‐Active M₈L₆ Cubic Hosts with Tetraphenylethylene Faces Encapsulate Organic Dyes for Light‐Driven H₂ Production

Photo-induced redox catalysis for proton reduction to hydrogen with homogeneous molecular systems using rhodium-based catalysts

A computational mechanistic investigation of hydrogen production in water using the [Rh^III(dmbpy)₂Cl₂]⁺/[Ru^II(bpy)₃]²⁺/ascorbic acid photocatalytic system

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Photocatalytic Hydrogen Production Using Models of the Iron–Iron Hydrogenase Active Site Dispersed in Micellar Solution

Cited by 62 publications

References 63 publications

Redox‐Active M8L6 Cubic Hosts with Tetraphenylethylene Faces Encapsulate Organic Dyes for Light‐Driven H2 Production

Redox‐Active M8L6 Cubic Hosts with Tetraphenylethylene Faces Encapsulate Organic Dyes for Light‐Driven H2 Production

Photo-induced redox catalysis for proton reduction to hydrogen with homogeneous molecular systems using rhodium-based catalysts

A computational mechanistic investigation of hydrogen production in water using the [RhIII(dmbpy)2Cl2]+/[RuII(bpy)3]2+/ascorbic acid photocatalytic system

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Redox‐Active M₈L₆ Cubic Hosts with Tetraphenylethylene Faces Encapsulate Organic Dyes for Light‐Driven H₂ Production

Redox‐Active M₈L₆ Cubic Hosts with Tetraphenylethylene Faces Encapsulate Organic Dyes for Light‐Driven H₂ Production

A computational mechanistic investigation of hydrogen production in water using the [Rh^III(dmbpy)₂Cl₂]⁺/[Ru^II(bpy)₃]²⁺/ascorbic acid photocatalytic system