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

Doyle, Richard L.; Lyons, Michael E. G.

doi:10.1039/c3cp43464h

Cited by 223 publications

(220 citation statements)

References 60 publications

(41 reference statements)

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“…Indeed, the surfaquo groups are specifically implicated as the catalytic centres in the hydrous oxide layers. 96,98 The latter assertion being supported by the pH dependence of the OER at hydrous iron oxide covered electrodes. In Fig.…”

Section: Interfacial Redox Chemistry Of Iron Based Electrodes In Alkamentioning

confidence: 80%

“…However, it has been noted previously that the A3/C2 peaks exhibit the usual characteristics of a hydrated or hyperextended oxide. Lyons and coworkers 84,96,98 have reported super-Nernstian potential-pH shifts for peaks A3/C2 of the order of dE/dpH = À2.303(3RT/2F) = À0.088 V per pH unit at T = 298 K, indicating that the oxide acquires a net negative charge in the oxidised state relative to the reduced state. Since traces of this peak appear even during the first sweep of a fresh, previously unused electrode, it is possible that at the outer regions of the oxide film the hydroxylation process outlined in eqn (27) is succeeded by a further stage which involves coordination of additional H 2 O and OH À species.…”

Section: Interfacial Redox Chemistry Of Iron Based Electrodes In Alkamentioning

confidence: 99%

“…Lyons and coworkers 96,98,99 found that hydrous Fe oxide layers exhibited distinct Tafel slopes for the OER depending on the concentration of NaOH used to prepare the film. In particular, it was observed that hydrous layers grown in high base concentrations had an associated Tafel slope of ca.…”

Section: Hydrous Oxide Electrodesmentioning

confidence: 99%

“…Indeed, the latter authors noted that by purposely dehydrating the hydrous Fe oxide layer, a film with a characteristic Tafel slope of 40 mV dec À1 could be transformed into one displaying a 60 mV dec À1 slope. 96,98 …”

Section: Hydrous Oxide Electrodesmentioning

confidence: 99%

“…These authors noted that the former Tafel slope is characteristic of a fresh electrode, whereas the latter value can be observed for an electrode that has undergone a significant number of polarisation experiments. More recently, Doyle and Lyons 96,98,99 have shown that the concentration of NaOH used in the preparation of hydrous Fe oxide layers has a significant influence on the observed Tafel slope for these electrode systems. It was observed that hydrous layers grown in high base concentrations had an associated Tafel slope of ca.…”

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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511

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: Interfacial Redox Chemistry Of Iron Based Electrodes In Alkamentioning

confidence: 80%

Section: Interfacial Redox Chemistry Of Iron Based Electrodes In Alkamentioning

confidence: 99%

Section: Hydrous Oxide Electrodesmentioning

confidence: 99%

Section: Hydrous Oxide Electrodesmentioning

confidence: 99%

Section: View Article Onlinementioning

confidence: 99%

See 3 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

511

565

View full text Add to dashboard Cite

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Highly Porous Materials as Tunable Electrocatalysts for the Hydrogen and Oxygen Evolution Reaction

Ledendecker

Clavel

Antonietti

et al. 2014

Adv Funct Materials

172

102

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wileyonlinelibrary.comContrarily, the OER (4OH − → O 2 + 4e − +2H 2 O in alkaline media) is more complicated due to the high number of steps involved. As in the HER, the best catalysts for the OER consist on less abundant and expensive materials such as RuO 2 or IrO 2 . Additionally, IrO 2 suffers from poor long term stability in alkaline solution. [ 6 ] Alternatives comprising more abundant and cheap materials as cobalt (Co), [ 7 ] nickel (Ni), [ 8,9 ] iron (Fe), [ 10 ] manganese (Mn), [ 11 ] their alloys (Ni-Co, Ni-Fe, Ni-Mo), oxides, [ 12 ] nitrides and carbides have been subject of intense research due to their promising electrocatalytic properties. For example, Ni based materials are considered to be one of the most effi cient non-noble electrocatalysts in alkaline solution. Moreover, modifications (i.e., alloying and doping) of Ni and nickel oxide based materials can result in higher activity, both for HER and OER. [ 13 ] One way to increase the catalytic behavior of these metals is by insertion of foreign dopants into materials possessing high surface areas. [ 14 ] Very recently, we showed the possibility to prepare highly porous Ni sponge materials embedded into amorphous C/N layers by means of a molten salt synthesis route. In general, the synthesis is considered relatively easy and safe, and a great variety of porous materials with respect to pore size distribution and surface area can be obtained. [ 15 ] Thereby, the salt can either act as the reaction medium (being inert to the desired reaction) or participate actively in the reaction. Careful design of the synthesis (salt melt composition, heating temperature, organic source, etc.) allows to tune the composition along with the chemical and the catalytic properties of the resulting material.Here we present a facile method to fabricate highly active manganese doped nickel-sponge materials for electrocatalytic applications (HER and OER). The effect of the manganese concentration on the chemical and the electrochemical properties is carefully studied. Moreover, we show that mild oxidation of these materials increases the surface area and alters the electrochemical activity. The composition, morphology and surface area of the resulting manganese doped nickel materials were characterized by X-ray diffraction (XRD), scanning electron microscopy (SEM), high-resolution transmission electron microscopy (HRTEM), high angle annular dark fi eld-scanning transmission electron microscopy (HAADF-STEM), energy dispersive X-ray spectroscopy (EDX), inductively coupled plasma atomic emission spectroscopy (ICP-OES), thermo gravimetric Highly Porous Materials as Tunable Electrocatalysts for the Hydrogen and Oxygen Evolution ReactionMarc Ledendecker , Guylhaine Clavel , Markus Antonietti , and Menny Shalom * The facile preparation of highly porous, manganese doped, sponge-like nickel materials by salt melt synthesis embedded into nitrogen doped carbon for electrocatalytic applications is shown. The incorporation of manganese into the porous structure enhances the nickel ...

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Dense Crystalline–Amorphous Interfacial Sites for Enhanced Electrocatalytic Oxygen Evolution

Qin

Liu

et al. 2021

Adv Funct Materials

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The crystalline-amorphous (c-a) heterostructure is verified as a promising design for oxygen evolution reaction (OER) catalysts due to the concerted advantages of the crystalline and amorphous phase. However, most heterostructures via asynchronous heterophase synthesis suffer from the limited synergistic effect because of the sparse c-a interfaces. Here, a highly efficient and stable OER electrocatalyst with dense c-a interfacial sites is reported by hybridizing crystalline Ag and amorphous NiCoMo oxides (NCMO) on the nickel foam (NF) via synchronous dual-phase synthetic strategy. In 1 m KOH, the as-obtained Ag/NCMO/NF catalyst exhibits a low OER overpotential of 243 mV to attain 10 mA cm −2 and a small Tafel slope of 67 mV dec −1 . Theoretical calculations indicate that the c-a interface can efficiently modulate the electronic structure of the interfacial sites and lower the OER overpotential. Besides, in situ Raman spectroscopy results demonstrate that the c-a interfacial sites can promote the irreversible phase transition to the metal oxy(hydroxide) active phase, and the dense c-a interfaces can stabilize the active phase during the whole OER process.

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

Cited by 223 publications

References 60 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

Highly Porous Materials as Tunable Electrocatalysts for the Hydrogen and Oxygen Evolution Reaction

Dense Crystalline–Amorphous Interfacial Sites for Enhanced Electrocatalytic Oxygen Evolution

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