Understanding voltammetry : simulation of electrode processes / by Richard G. Compton (Oxford University, UK, and University of Murcia, Spain), Eduardo Laborda (Oxford University, UK), and Kristopher R. Ward (Oxford University, UK).

By:

Compton, R. G [Author]

Contributor(s):

Material type: Text

text

Media type:

computer

Carrier type:

online resource

ISBN:

9781783263257

Subject(s):

Genre/Form:

Electronic Books.

LOC classification:

QD116 .U534 2013

Online resources:

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Available additional physical forms:

Contents:

2. Mathematical model of an electrochemical system. 2.1. Cyclic voltammetry. 2.2. Diffusion: Fick's second law. 2.3. Boundary conditions. 2.4. Current. 2.5. Dimensionless coordinates. 2.6. Summary -- 3. Numerical solution of the model system. 3.1. Finite differences. 3.2. Time evolution: discretising Fick's second law. 3.3. The Thomas algorithm. 3.4. Simulation procedure. 3.5. Checking results. 3.6. Performance and runtime analysis -- 4. Diffusion-only electrochemical problems in one-dimensional systems. 4.1. Unequally spaced grids. 4.2. Finite electrode kinetics. 4.3. Unequal diffusion coefficients. 4.4. Other one-dimensional electrode geometries -- 5. First-order chemical kinetic mechanisms. 5.1. First-order EC[symbol] mechanism: basic concepts. 5.2. First-order catalytic mechanism: coupled equation systems. 5.3. LU decomposition and extended Thomas algorithm. 5.4. First-order EC[symbol] mechanism: including a third species. 5.5. Multiple-electron transfer processes. 5.6. Heterogeneous chemical processes -- 6. Second-order chemical kinetic mechanisms. 6.1. Second-order catalytic mechanism: the Newton-Raphson method. 6.2. Multiple-electron transfers: adaptive spatial grids. 6.3. Adsorption -- 7. Electrochemical simulation in weakly supported media. 7.1. The Nernst-Planck-Poisson problem. 7.2. Weakly supported cyclic voltammetry and chronoamperometry -- 8. Hydrodynamic voltammetry. 8.1. Rotating disc electrode. 8.2. Channel electrode -- 9. Two-dimensional systems: microdisc electrodes. 9.1. Microdisc electrodes: the model. 9.2. Numerical solution. 9.3. Implementation. 9.4. Microband electrodes -- 10. Heterogeneous surfaces. 10.1. Arrays of microdisc electrodes. 10.2. Microband arrays. 10.3. Porous electrodes. 10.4. Conclusion.

Subject: This is the first textbook in the field of electrochemistry that will teach experimental electrochemists how to carry out simulation of electrode processes. Processes at both macro- and micro-electrodes are examined and the simulation of both diffusion-only and diffusion-convection processes are addressed. The simulation of processes with coupled homogeneous kinetics and at microelectrode arrays are further discussed. Over the course of the book the reader's understanding is developed to the point where they will be able to undertake and solve research-level problems. The book leads the reader through from a basic understanding of the principles underlying electrochemical simulation to the development of computer programs which describe the complex processes found in voltammetry. This is the third book in the "Understanding Voltammetry" series, published with Imperial College Press and written by the Compton group. Other books in the series include "Understanding Voltammetry", written by Richard G. Compton with Craig Banks and also "Understanding Voltammetry: Problems and Solutions" (2012) written by Richard G. Compton with Christopher Batchelor-McAuley and Edmund Dickinson. These are and continue to be successful textbooks for graduates in electrochemistry and electroanalytical studies.

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Holdings
Item type	Current library	Collection	Call number	URL	Status	Date due	Barcode
Online Book (LOGIN USING YOUR MY CIU LOGIN AND PASSWORD)	G. Allen Fleece Library ONLINE	Non-fiction	QD116.64 (Browse shelf(Opens below))	Link to resource	Available		ocn864899978

Includes bibliographies and index.

1. Introduction. 1.1. Electrochemical systems. 1.2. Voltammetric techniques. 1.3. Finite difference methods. 1.4. Voltammetry: a selected bibliography -- 2. Mathematical model of an electrochemical system. 2.1. Cyclic voltammetry. 2.2. Diffusion: Fick's second law. 2.3. Boundary conditions. 2.4. Current. 2.5. Dimensionless coordinates. 2.6. Summary -- 3. Numerical solution of the model system. 3.1. Finite differences. 3.2. Time evolution: discretising Fick's second law. 3.3. The Thomas algorithm. 3.4. Simulation procedure. 3.5. Checking results. 3.6. Performance and runtime analysis -- 4. Diffusion-only electrochemical problems in one-dimensional systems. 4.1. Unequally spaced grids. 4.2. Finite electrode kinetics. 4.3. Unequal diffusion coefficients. 4.4. Other one-dimensional electrode geometries -- 5. First-order chemical kinetic mechanisms. 5.1. First-order EC[symbol] mechanism: basic concepts. 5.2. First-order catalytic mechanism: coupled equation systems. 5.3. LU decomposition and extended Thomas algorithm. 5.4. First-order EC[symbol] mechanism: including a third species. 5.5. Multiple-electron transfer processes. 5.6. Heterogeneous chemical processes -- 6. Second-order chemical kinetic mechanisms. 6.1. Second-order catalytic mechanism: the Newton-Raphson method. 6.2. Multiple-electron transfers: adaptive spatial grids. 6.3. Adsorption -- 7. Electrochemical simulation in weakly supported media. 7.1. The Nernst-Planck-Poisson problem. 7.2. Weakly supported cyclic voltammetry and chronoamperometry -- 8. Hydrodynamic voltammetry. 8.1. Rotating disc electrode. 8.2. Channel electrode -- 9. Two-dimensional systems: microdisc electrodes. 9.1. Microdisc electrodes: the model. 9.2. Numerical solution. 9.3. Implementation. 9.4. Microband electrodes -- 10. Heterogeneous surfaces. 10.1. Arrays of microdisc electrodes. 10.2. Microband arrays. 10.3. Porous electrodes. 10.4. Conclusion.

This is the first textbook in the field of electrochemistry that will teach experimental electrochemists how to carry out simulation of electrode processes. Processes at both macro- and micro-electrodes are examined and the simulation of both diffusion-only and diffusion-convection processes are addressed. The simulation of processes with coupled homogeneous kinetics and at microelectrode arrays are further discussed. Over the course of the book the reader's understanding is developed to the point where they will be able to undertake and solve research-level problems. The book leads the reader through from a basic understanding of the principles underlying electrochemical simulation to the development of computer programs which describe the complex processes found in voltammetry. This is the third book in the "Understanding Voltammetry" series, published with Imperial College Press and written by the Compton group. Other books in the series include "Understanding Voltammetry", written by Richard G. Compton with Craig Banks and also "Understanding Voltammetry: Problems and Solutions" (2012) written by Richard G. Compton with Christopher Batchelor-McAuley and Edmund Dickinson. These are and continue to be successful textbooks for graduates in electrochemistry and electroanalytical studies.

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