Redox switching and oxygen evolution electrocatalysis in polymeric iron oxyhydroxide films

Lyons, Michael E. G.; Brandon, Michael

doi:10.1039/b815338h

Cited by 87 publications

(115 citation statements)

References 49 publications

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“…In such cases, the experimentally observed kinetic parameters represent a combination of the parameters expected for the competing pathways, the exact value of which depends on the fraction of catalytic sites following each individual pathway. Then again, Lyons and Brandon 92 have shown that the fractional reaction order m OH À = 1.5 observed for an 'aged' passive oxide coated iron electrode can be rationalised by admitting Temkin rather than Langmuir adsorption conditions. (b) Open circuit potential decay.…”

Section: View Article Onlinementioning

confidence: 98%

“…Lyons and coworkers 17,92 have applied the Aoki model to the voltammetric data obtained for hydrous Fe oxide coated electrodes. In particular, they note that the i p /v 1/2 proportionality can be readily obtained at reasonable values of sweep rate for thick layers whereas the i p /v proportionality, suggesting the operation of Nernstian equilibrium throughout the dispersed layer during redox switching, is observed over an extended range of sweep rates for thin layers.…”

Section: Charge Transport In Transition Metal Oxidesmentioning

confidence: 99%

“…25, R far is calculated from the fitting parameters as R far = R p + R s . 92,96,98 At an oxygen evolution overpotential Z where simple Tafel behaviour prevails, the current density i is related to Z via the following expression, 92,96,98,296 …”

Section: View Article Onlinementioning

confidence: 99%

“…332 On the other hand, charge percolation proceeds comparatively easily and quickly through the outer, hydrous, polymeric oxide region; the average rate of charge diffusion for a hydrous oxide covered Fe electrode in base is comparable to that of electrodes modified by redox polymers such as poly(pyrrole). 17,92 Interestingly, a duplex model was also specifically proposed for the anodic oxide formed on Au electrodes 334 -the very system for which the twin barrier model was originally applied to the OER. 332 The final mechanism to be discussed pertains to the hydrous oxide coated metal substrates.…”

Section: View Article Onlinementioning

confidence: 99%

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

Doyle

Godwin

Brandon

et al. 2013

Phys. Chem. Chem. Phys.

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537

565

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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: 98%

Section: Charge Transport In Transition Metal Oxidesmentioning

confidence: 99%

Section: View Article Onlinementioning

confidence: 99%

Section: View Article Onlinementioning

confidence: 99%

See 2 more Smart Citations

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

Doyle

Godwin

Brandon

et al. 2013

Phys. Chem. Chem. Phys.

Self Cite

537

565

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show abstract

“…It has been noted that dispersed hydrated oxide materials exhibit good electrocatalytic potentiality due to their skeletal nature as the latter structural feature permits a major increase in the number of oxyions participating in the electrode reaction. 11,30 Indeed, with microdispersed species the boundary between the solid and aqueous phase may be nebulous as the two phases virtually intermingle. This will be an important consideration when a model for the OER is developed.…”

Section: Preparation and Voltammetry Of Hydrous Iron Oxidesmentioning

confidence: 99%

An electrochemical impedance study of the oxygen evolution reaction at hydrous iron oxide in base

Doyle

Lyons

2013

Phys. Chem. Chem. Phys.

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233

209

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The oxygen evolution reaction at multi-cycled iron oxy-hydroxide films in aqueous alkaline solution is discussed. Steady-state Tafel plot analysis and electrochemical impedance spectroscopy have been used to elucidate the kinetics and mechanism of oxygen evolution. Tafel slopes of ca. 60 mV dec À1 and 40 mV dec À1 are found at low overpotentials depending on the oxide growth conditions, with an apparent Tafel slope of ca. 120 mV dec À1 at high overpotentials. Reaction orders of ca. 0.5 and 1.0 are observed at low and high overpotentials, again depending on the oxide growth conditions. A mechanistic scheme involving the active participation of octahedrally coordinated anionic iron oxyhydroxide surfaquo complexes, which form the porous hydrous layer, is proposed. The latter structure contains considerable quantities of water molecules which facilitate hydroxide ion discharge at the metal site during active oxygen evolution. This work brings together current research in heterogeneous electrocatalysis and homogeneous molecular catalysis for water oxidation.

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Earth‐Abundant Metal‐Based Nanomaterials for Electrochemical Water Splitting

Zheng

Lee

2022

Functional Nanomaterials

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Redox switching and oxygen evolution electrocatalysis in polymeric iron oxyhydroxide films

Cited by 87 publications

References 49 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

An electrochemical impedance study of the oxygen evolution reaction at hydrous iron oxide in base

Earth‐Abundant Metal‐Based Nanomaterials for Electrochemical Water Splitting

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