A molecular ruthenium catalyst with water-oxidation activity comparable to that of photosystem II

Duan, Lele; Bozoglián, Fernando; Mandal, Sukanta; Stewart, Beverly; Privalov, Timofei; Llobet, Antoni; Sun, Licheng

doi:10.1038/nchem.1301

Cited by 1,158 publications

(1,280 citation statements)

References 26 publications

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“…31 is analogous to those depicted for various homogeneous catalyst systems. 316,323,324 This is not unexpected given the very dispersed and somewhat tenuous nature of the catalytically active hydrous oxide layer. A common feature of these reaction schemes is that the initial catalytic step involves the deprotonation of a metal coordinated water molecule.…”

Section: View Article Onlinementioning

confidence: 86%

Redox and electrochemical water splitting catalytic properties of hydrated metal oxide modified electrodes

Doyle

Godwin

Brandon

et al. 2013

Phys. Chem. Chem. Phys.

507

551

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This paper presents a review of the redox and electrocatalytic properties of transition metal oxide electrodes, paying particular attention to the oxygen evolution reaction. Metal oxide materials may be prepared using a variety of methods, resulting in a diverse range of redox and electrocatalytic properties. Here we describe the most common synthetic routes and the important factors relevant to their preparation. The redox and electrocatalytic properties of the resulting oxide layers are ascribed to the presence of extended networks of hydrated surface bound oxymetal complexes termed surfaquo groups. This interpretation presents a possible unifying concept in water oxidation catalysis -bridging the fields of heterogeneous electrocatalysis and homogeneous molecular catalysis. In contextOver the past 50 years considerable research efforts have been devoted to the realisation of efficient, economical and renewable energy sources. Metal oxide materials have played a large part in this drive with demonstrated applications at both the research and commercial level. Their use in areas such as batteries, fuel cells and water electrolysis has resulted in the development of materials with a diverse range of structural and chemical properties. In all cases, understanding the fundamental electrochemistry of the material can be invaluable for rational design and optimisation. This review focuses on the redox, charge transport and electrocatalytic properties of transition metal oxide electrodes as they pertain to the electrolytic splitting of water. Particular emphasis is placed on the nature of the active surface which is interpreted in terms of hydrated interlinked oxymetal complexes termed surfaquo groups. In this way, the review seeks to bridge the gap between heterogeneous electrocatalysis and homogeneous molecular catalysis for water oxidation, areas of considerable modern interest and activity.

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Section: View Article Onlinementioning

confidence: 86%

Redox and electrochemical water splitting catalytic properties of hydrated metal oxide modified electrodes

Doyle

Godwin

Brandon

et al. 2013

Phys. Chem. Chem. Phys.

507

551

View full text Add to dashboard Cite

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“…18 A complete Pourbaix diagram is offered in Figure 2B where the zones of predominant species derived from 2 II (H2O) with different electron/proton content are shown. An interesting feature of the Pourbaix diagram for 2 IV (OH) + is the pH 10-14 zone, that has been built by extrapolating the values of the V/IV couple at this pH and by assuming that the redox potential for the Ru V =O/Ru IV =O couple for [Ru IV (bda)(Me-py)2(O) eq ], 3 IV (O) (1.12 V), 15 is the same as for 2 IV (O) (Me-py is 4-methylpyridine). This assumption is based on Lever's approach 22,23,24 where it is shown that the Ru III /Ru II couple for a set of complexes can be calculated based on additive contribution of their respective ligands bonded to the first coordination sphere.…”

Section: Redox Properties and Water Oxidation Catalysismentioning

confidence: 99%

“…4 Molecular transition metal complexes constitute an excellent platform to examine these factors since significant information based on an arsenal of spectroscopic, electrochemical and analytical techniques can be used together with the valuable complementary information provided by computational studies. 5,6,7,8,9,10,11,12,13,14 The best water oxidation catalysts reported today are based on seven coordinated Ru complexes containing dianionic ligands such as [2,2'-bipyridine]-6,6'-dicarboxylato (bda 2-) 15,16,17 and [2,2':6',2''-terpyridine]-6,6''-dicarboxylato (tda 2-) (see Figure 1 for drawn structures of these ligands). Particularly impressive is the seven coordinate complex [Ru IV (tda--N 3 O)(py)2(O) eq ], 4 IV (O), (the superscript in roman numbers indicates the formal oxidation state of Ru; py is pyridine; the "eq" superscript means equatorial) that is capable of oxidizing water to dioxygen at maximum turnover frequencies (TOFMAX) of 7,700 s -1 and 50,000 s -1 at pH = 7.0 and pH = 10.0 respectively.…”

Section: Introductionmentioning

confidence: 99%

Hydrogen Bonding Rescues Overpotential in Seven-Coordinated Ru Water Oxidation Catalysts

et al. 2017

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In this work we describe the synthesis, structural characterization and redox properties of two Ru complexes containing the dianionic potentially pentadentate [2,2':6',2''-terpyridine]-6,6''-dicarboxylate (tda 2-) ligand that coordinates Ru at the equatorial plane and with additional pyridine or dmso acting as monondentate ligand in the axial positions: [Ru II (tda--N 3 O)(py)(dmso)], 1 II and [Ru III (tda--N 3 O 2 )(py)(H2O) ax ] + , 2 III (H2O) + . Complex 1 II has been characterized by single crystal XRD in the solid state and in solution by NMR spectroscopy. The redox properties of 1 II and 2 III (H2O) + have been thoroughly investigated by means of cyclic voltammetry (CV) and differential pulse voltammetry (DPV). Complex 2 II (H2O) displays poor catalytic activity with regard to the oxidation of water to dioxygen and its properties have been analyzed based on foot of the wave analysis (FOWA) and catalytic Tafel plots. The activity of 2 II (H2O) has been compared with related water oxidation catalysts (WOCs) previously described in the literature. Despite its moderate activity, 2 II (H2O) constitutes the cornerstone that has triggered the rationalization of the different factors that govern overpotentials as well as efficiencies in molecular water oxidation catalysts (WOCs). The present work uncovers the interplay between different parameters namely, coordination number, number of anionic groups bonded to the first coordination sphere of the metal center, water oxidation catalysis overpotential, pKa and hydrogen bonding and the performance of a given WOC. It thus establishes the basic principles for the design of efficient WOCs operating at low overpotentials.

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“…[6][7][8][9][10][11][12] A photoelectrochemical solar fuel cell device combines the functions of light harvesting, charge separation and catalysis. [13][14][15] In the last decade several systems have been proposed employing either metal oxide nanoparticles 8,[16][17][18][19][20][21][22][23][24] or molecular complexes 8,[25][26][27][28] as water oxidation catalyst (WOC). Furthermore, the coupling between the WOC, the chromophore and an electron accepting semiconductor into a photoanode has been achieved through co-absorption of both the catalyst and the chromophore 16,[29][30][31][32] or through dye-WOC supramolecular complexes.…”

Section: Introductionmentioning

confidence: 99%

A Dynamic View of Proton-Coupled Electron Transfer in Photocatalytic Water Splitting

et al. 2016

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A molecular ruthenium catalyst with water-oxidation activity comparable to that of photosystem II

Cited by 1,158 publications

References 26 publications

Redox and electrochemical water splitting catalytic properties of hydrated metal oxide modified electrodes

Redox and electrochemical water splitting catalytic properties of hydrated metal oxide modified electrodes

Hydrogen Bonding Rescues Overpotential in Seven-Coordinated Ru Water Oxidation Catalysts

A Dynamic View of Proton-Coupled Electron Transfer in Photocatalytic Water Splitting

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