The latest edition of a classic textbook in electrochemistry

The third edition of Electrochemical Methods has been extensively revised to reflect the evolution of electrochemistry over the past two decades, highlighting significant developments in the understanding of electrochemical phenomena and emerging experimental tools, while extending the book's value as a general introduction to electrochemical methods.

This authoritative resource for new students and practitioners provides must-have information crucial to a successful career in research. The authors focus on methods that are extensively practiced and on phenomenological questions of current concern.

This latest edition of Electrochemical Methods contains numerous problems and chemical examples, with illustrations that serve to illuminate the concepts contained within in a way that will assist both student and mid-career practitioner.

Significant updates and new content in this third edition include:

• An extensively revised introductory chapter on electrode processes, designed for new readers coming into electrochemistry from diverse backgrounds
• New chapters on steady-state voltammetry at ultramicroelectrodes, inner-sphere electrode reactions and electrocatalysis, and single-particle electrochemistry
• Extensive treatment of Marcus kinetics as applied to electrode reactions, a more detailed introduction to migration, and expanded coverage of electrochemical impedance spectroscopy
• The inclusion of Lab Notes in many chapters to help newcomers with the transition from concept to practice in the laboratory

The new edition has been revised to address a broader audience of scientists and engineers, designed to be accessible to readers with a basic foundation in university chemistry, physics and mathematics. It is a self-contained volume, developing all key ideas from the fundamental principles of chemistry and physics.

Perfect for senior undergraduate and graduate students taking courses in electrochemistry, physical and analytical chemistry, this is also an indispensable resource for researchers and practitioners working in fields including electrochemistry and electrochemical engineering, energy storage and conversion, analytical chemistry and sensors.

Table of Contents

Chapter 1 Overview of Electrode Processes

Chapter 2 Potentials and Thermodynamics of Cells

Chapter 3 Basic Kinetics of Electrode Reactions

Chapter 4 Mass Transfer by Migration and Diffusion

Chapter 5 Steady-State Voltammetry at Ultramicroelectrodes

Chapter 6 Transient Methods Based on Potential Steps

Chapter 7 Linear Sweep and Cyclic Voltammetry

Chapter 8 Polarography, Pulse Voltammetry, and Square-Wave Voltammetry

Chapter 9 Controlled-Current Techniques

Chapter 10 Methods Involving Forced Convection-Hydrodynamic Methods

Chapter 11 Electrochemical Impedance Spectroscopy and ac Voltammetry

Chapter 12 Bulk Electrolysis

Chapter 13 Electrode Reactions with Coupled Homogeneous Chemical Reactions

Chapter 14 Double-Layer Structure and Adsorption

Chapter 15 Inner-Sphere Electrode Reactions and Electrocatalysis

Chapter 16 Electrochemical Instrumentation

Chapter 17 Electroactive Layers and Modified Electrodes

Chapter 18 Scanning Electrochemical Microscopy

Chapter 19 Single-Particle Electrochemistry

Chapter 20 Photoelectrochemistry and Electrogenerated Chemiluminescence

Chapter 21 In situ Characterization of Electrochemical Systems

A Mathematical Methods

B Basic Concepts of Simulation

C Reference Tables

About the Authors

Allen J. Bard is Professor and Hackerman-Welch Regents Chair in Chemistry at the University of Texas at Austin in the United States. His research is focused on the application of electrochemical methods to the study of chemical problems.

Larry R. Faulkner is President Emeritus of the University of Texas at Austin in the United States. He has served on the chemistry faculties of Harvard University, the University of Illinois, and the University of Texas.

Henry S. White is Distinguished Professor and John A. Widstoe Presidential Chair in the Department of Chemistry at the University of Utah in the United States. His research is focused on experimental and theoretical aspects of electrochemistry.