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Flow influenced electrochemical corrosion of nickel aluminium bronze – Part I. Cathodic polarisation

Flow influenced electrochemical corrosion of nickel aluminium bronze – Part I. Cathodic polarisation
Flow influenced electrochemical corrosion of nickel aluminium bronze – Part I. Cathodic polarisation
The cathodic polarisation behaviour of CA 104 nickel aluminium bronze (NAB) has been examined in fully characterised seawaters (filtered and artificial) using the rotating disc electrode (RDE) and the rotating cylinder electrode (RCE). Linear sweep voltammetry and a potential step, current transient technique were used to examine the charge transfer and mass transfer controlled cathodic response as a function of both laminar and turbulent fluid flow. For freshly polished surfaces, the rate of irreversible charge transfer controlled oxygen reduction is controlled by the exchange of a single electron and hydrogen evolution is only significant at potentials more negative than approximately –1.0 V vs. the saturated calomel electrode (SCE).
flow-enhanced corrosion, mass transfer, nickel aluminium bronze (nab), oxygen reduction, rotating cylinder electrode (rce), rotating disc electrode (rde), seawater
1235-1240
Kear, G.
eb25b3ff-b75c-47ba-b545-233fee85b0a3
Barker, B.D.
74e8d2f7-7cd3-418c-8190-ebf2197b51b9
Stokes, K.
5fb4e7f7-2f7e-4e6e-a045-6d7690626695
Walsh, F.C.
309528e7-062e-439b-af40-9309bc91efb2
Kear, G.
eb25b3ff-b75c-47ba-b545-233fee85b0a3
Barker, B.D.
74e8d2f7-7cd3-418c-8190-ebf2197b51b9
Stokes, K.
5fb4e7f7-2f7e-4e6e-a045-6d7690626695
Walsh, F.C.
309528e7-062e-439b-af40-9309bc91efb2

Kear, G., Barker, B.D., Stokes, K. and Walsh, F.C. (2004) Flow influenced electrochemical corrosion of nickel aluminium bronze – Part I. Cathodic polarisation. Journal of Applied Electrochemistry, 34 (12), 1235-1240. (doi:10.1007/s10800-004-1758-1).

Record type: Article

Abstract

The cathodic polarisation behaviour of CA 104 nickel aluminium bronze (NAB) has been examined in fully characterised seawaters (filtered and artificial) using the rotating disc electrode (RDE) and the rotating cylinder electrode (RCE). Linear sweep voltammetry and a potential step, current transient technique were used to examine the charge transfer and mass transfer controlled cathodic response as a function of both laminar and turbulent fluid flow. For freshly polished surfaces, the rate of irreversible charge transfer controlled oxygen reduction is controlled by the exchange of a single electron and hydrogen evolution is only significant at potentials more negative than approximately –1.0 V vs. the saturated calomel electrode (SCE).

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More information

Published date: 2004
Keywords: flow-enhanced corrosion, mass transfer, nickel aluminium bronze (nab), oxygen reduction, rotating cylinder electrode (rce), rotating disc electrode (rde), seawater
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Identifiers

Local EPrints ID: 23115
URI: http://eprints.soton.ac.uk/id/eprint/23115
DOI: doi:10.1007/s10800-004-1758-1
PURE UUID: e6f8a5db-fecd-49a4-b299-ce439ac186a5

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Date deposited: 23 Mar 2006
Last modified: 15 Mar 2024 06:44

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Contributors

Author: G. Kear
Author: B.D. Barker
Author: K. Stokes
Author: F.C. Walsh

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