Rotating Disk Ion Selective Electrodes

John Cassidy; David Mullen; Karen Casey; Patrick Cullen

doi:10.1002/elan.1140081013

Rotating Disk Ion Selective Electrodes

John Cassidy, David Mullen, Karen Casey, Patrick Cullen

School of Chemical and BioPharmaceutical Science

Research output: Contribution to journal › Article › peer-review

Abstract

A simulation was undertaken to predict the transient potential response following a concentration step at a rotating disk electrode comprised of an ion selective layer. A basis for this simulation was that the potential response would be independent of rotation rate since the diffusion layer is larger than the double layer at the electrode. In practice it was found that the potential response does vary with rotation rate. The response was such that the apparent concentration of the analyte in solution decreased with increased rotation rate. The reason lor this behavior is due to the disruption of the double layer at the electrode surface by convection.

Original language	English
Pages (from-to)	918-921
Number of pages	4
Journal	Electroanalysis
Volume	8
Issue number	10
DOIs	https://doi.org/10.1002/elan.1140081013
Publication status	Published - Oct 1996

Keywords

Flowing streams
Potentiometry
Rotating disk electrode

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https://arrow.tudublin.ie/scschcpsart/11Licence: CC BY-NC-SA

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title = "Rotating Disk Ion Selective Electrodes",

abstract = "A simulation was undertaken to predict the transient potential response following a concentration step at a rotating disk electrode comprised of an ion selective layer. A basis for this simulation was that the potential response would be independent of rotation rate since the diffusion layer is larger than the double layer at the electrode. In practice it was found that the potential response does vary with rotation rate. The response was such that the apparent concentration of the analyte in solution decreased with increased rotation rate. The reason lor this behavior is due to the disruption of the double layer at the electrode surface by convection.",

keywords = "Flowing streams, Potentiometry, Rotating disk electrode",

author = "John Cassidy and David Mullen and Karen Casey and Patrick Cullen",

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AU - Casey, Karen

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N2 - A simulation was undertaken to predict the transient potential response following a concentration step at a rotating disk electrode comprised of an ion selective layer. A basis for this simulation was that the potential response would be independent of rotation rate since the diffusion layer is larger than the double layer at the electrode. In practice it was found that the potential response does vary with rotation rate. The response was such that the apparent concentration of the analyte in solution decreased with increased rotation rate. The reason lor this behavior is due to the disruption of the double layer at the electrode surface by convection.

AB - A simulation was undertaken to predict the transient potential response following a concentration step at a rotating disk electrode comprised of an ion selective layer. A basis for this simulation was that the potential response would be independent of rotation rate since the diffusion layer is larger than the double layer at the electrode. In practice it was found that the potential response does vary with rotation rate. The response was such that the apparent concentration of the analyte in solution decreased with increased rotation rate. The reason lor this behavior is due to the disruption of the double layer at the electrode surface by convection.

KW - Flowing streams

KW - Potentiometry

KW - Rotating disk electrode

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U2 - 10.1002/elan.1140081013

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JO - Electroanalysis

JF - Electroanalysis

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ER -

Rotating Disk Ion Selective Electrodes

Abstract

Keywords

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