The Silver-Silver Oxide Electrode

Cahan, B. D.; Ockerman, J. B.; Amlie, R. F.; Rüetschi, Paul

doi:10.1149/1.2427827

Cited by 61 publications

(53 citation statements)

References 5 publications

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“…6, a roughness factor of approximately 200 must be assumed for an electrode which is reduced electrochemically. For comparison purposes, polarization curves for electrodes etched in 1 : 1 nitric acid were similarly analyzed, and led to roughness factors of 15 to 20, in good agreement with those reported by Cahan et al (24) for silver treated in this manner. There seems to be no reason, therefore, to reject the roughness factor value of 200 for electrochemically reduced electrodes.…”

Section: Effect Of Electrode Treatmentsupporting

confidence: 81%

Anodic behavior of silver in alkaline solutions

Dignam¹,

Barrett²,

Nagy³

1969

Can. J. Chem.

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Data, covering a range of pH and temperature, were obtained for the anodic oxidation of electropolished silver and the results compared with electrodes which had undergone repeated oxidation and reduction cycles. The behavior of the electrode is, in the main, complex, showing, for example, autopotential cycling under certain galvanostatic conditions (-3 pA/cmZ, 25 "C, 0.7 N NaOH), the period of oscillation being about t h. Several other hitherto unreported phenomena were also observed. The main conclusions reached are (i) that 2 different mechanisms are involved in the anodic formation of AgzO on silver electrodes in basic electrolytes resulting in 2 types of film, 1 mechanism involves a dissolution-precipitation process, the other possibly a direct interfacial reaction; (ii) that the reduction of anodically formed Ag,O films either electrochemically or in hydrogen at 800 OC leaves behind a highly porous,layer of silver metal; and (iii) that the limiting AgzO film thickness is probably determined by a diffusion process occurring within the film.

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Section: Effect Of Electrode Treatmentsupporting

confidence: 81%

Anodic behavior of silver in alkaline solutions

Dignam¹,

Barrett²,

Nagy³

1969

Can. J. Chem.

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“…Dirkse [19] suggested that the peak is due to a maximum ohmic potential drop associated with a complete film of Ag20. Cahan et al [22] concluded from measurements of the resistance of the Ag20 layer that the peak is not directly due to an ohmic resistance effect but to concentration of the current in small localized areas, where the conversion of Ag20 to AgO can proceed. Yoshizawa and Takehara [24] believed that the peak is generated because 02-ions can diffuse more easily in the AgO layer than in the Ag20 layer.…”

Section: Galvanostatic Measurementsmentioning

confidence: 99%

Electrochemical formation and reduction of silver oxides in alkaline media

Droog¹

1980

Journal of Electroanalytical Chemistry

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The anodic oxidation of silver electrodes in NaOH solution and the reduction of the silver oxides formed were studied by potential step chronoamperometry. Oxidation of Ag to Ag20 is a diffusion-controlled reaction, the diffusion control being established in the solid phase. Oxidation of Ag20 to AgO proceeds via a nucleation and growth-controlled process. The amount of AgO decreased with increasing step height. The current--time curves for this reaction have been analysed with the Kolmogoroff--Avrami equation. Reduction of AgO to Ag20 occurs initially on the outside of the electrode, and the rate of the reaction is limited by diffusion of ions across the thickening layer of Ag20. Reduction of Ag20 to Ag proceeds via a nucleation and growth reaction.

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“…The reference electrode was a mercury/mercuric oxide electrode prepared a s described by Cahan et a/. (9). It was located in a compartment which contained a 20% aqueous solution of ammonium pentaborate.…”

Section: Tlie Cell a R~d Electrodesmentioning

confidence: 99%

“…Accordingly, [14] may be written which on using the boundary conditions [I 11 and [I 51 (i.c. P,(Q = 0) = coxkE,, k = 2, 3) may be integrated to yield the following expression for P, From [6] and [ l l ] , BE, = BSE2 for Q > 0 , so that [5] may be written Eliminating P and then PI using [13] and [9], and eliminating using [7] gives Substituting for P2 and P, from [A51 leads to an integral equation in E. Elimination of the two integrals by the usual method of isolation and differentiation leads to the following second order differential equation in the excess field, A E = E -E 2 .…”

Section: Decliy Rynf Excess Fieldmentioning

confidence: 99%

Transient Response of the System Al/Al₂O₃/Electrolyte. Part I. Galvanostatic Transients

Goad¹,

Dignam²

1972

Can. J. Chem.

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Voltage transients under galvanostatic conditions are investigated for the system AI/Al,O,/electrolyte (glycol-borate) and the results, along with similar results obtained by Dewald for the system Ta/Ta,O,/ electrolyte (0.1 N H'SO,), are analyzed according to the dielectric relaxation model due to Dignam. This model accounts for the general form of the transients, but systematic discrepancies are apparent. Modification of the model to include two independent ion-current-driven dielectric relaxation processes gives essentially exact agreement with the data and values for the constants in accord with those obtained earlier from potentiostatic transient measurements.--Nous etudions les transitions de voltage sous des conditions galvanostatiques pour le systeme AI/AI,O,/ electrolyte (glycol-borate) et nous analysons les resultats, de mime que les resultats similaires obtenus par Dewald pour le systeme Ta/TaZO,/electrolyte (0

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The Silver-Silver Oxide Electrode

Cited by 61 publications

References 5 publications

Anodic behavior of silver in alkaline solutions

Anodic behavior of silver in alkaline solutions

Electrochemical formation and reduction of silver oxides in alkaline media

Transient Response of the System Al/Al₂O₃/Electrolyte. Part I. Galvanostatic Transients

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The Silver-Silver Oxide Electrode

Cited by 61 publications

References 5 publications

Anodic behavior of silver in alkaline solutions

Anodic behavior of silver in alkaline solutions

Electrochemical formation and reduction of silver oxides in alkaline media

Transient Response of the System Al/Al2O3/Electrolyte. Part I. Galvanostatic Transients

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Transient Response of the System Al/Al₂O₃/Electrolyte. Part I. Galvanostatic Transients