Note: Cover -- Half Title -- Title Page -- Copyright Page -- Introduction to the Series -- Contributors to Volume 22 -- Table of Contents -- Contents of Other Volumes -- Looking at the Metal/Solution Interface With the Electrochemical Quartz-Crystal Microbalance: Theory and Experiment -- I. Introduction -- A. Is It Really a Microbalance? -- B. Applications of the Quartz Crystal Microbalance -- C. The Impedance Spectrum of the EQCM -- D. Outline of This Chapter -- II. Theoretical Interpretation of the QCM Response -- A. Impedance -- B. The Effect of Thin Surface Films -- C. The Quartz Crystal Operating in Contact with a Liquid -- D. Quartz Crystals with Rough Surfaces -- III. Electrical Double Layer/Electrostatic Adsorption -- A. Introduction -- B. Some Typical Results -- C. The Potential Dependence of the Frequency -- IV. Adsorption Studies -- A. The Adsorption of Organic Substances -- B. The Adsorption of Inorganic Species -- V. Metal Deposition -- A. Deposition on the Same Metal Substrate -- B. Early Stages of Metal Deposition on a Foreign Substrate -- VI. The Influence of Roughness on the Response of the QCM in Liquids -- A. The Nonelectrochemical Case -- B. The Electrochemical Case -- VII. Conclusion -- VIII. Appendix -- A. Nonuniform Film on the Surface -- B. Experimental Remarks -- References -- The Indirect Laser-Induced Temperature Jump Method for Characterizing Fast Interfacial Electron Transfer: Concept, Application, and Results -- I. Introduction -- A. Why Measure Fast Interfacial Electron Transfer Rate Constants? And How? -- B. Background -- C. The Underlying Principles of the ILIT Method-The Short Version -- D. Definition of Terms -- II. The Evolution of the ILIT Method for the Study of Fast Interfacial Electron Transfer Kinetics -- A. The Temperature-Jump Approach for Studies of Homogeneous Kinetics. , B. The Temperature-Jump Approach for Studies of Interfacial Kinetics -- III. Relevant Electron Transfer Theory: Marcus's Description of Heterogeneous Nonadiabatic Electron Transfer Reactions -- A. Chidsey's Approach -- B. Temperature Dependence -- C. How Well Does the Butler-Volmer Expression Approximate Marcus's Formalism? -- IV. Analysis of the ILIT Response -- A. Response of the Open-Circuit Electrode Potential to a Change in the Interfacial Temperature in the Presence of a Perfectly Reversible Redox Couple Attached to the Electrode Surface -- B. The Relaxation of the ILIT Response When the Rate of Electron Transfer Is Not Infinitely Fast -- C. When Is the ILIT Response Purely Thermal (i.e., Devoid of Kinetic Information)? -- D. The Shape of the Ideal ILIT Perturbation -- E. Nonidealities of the Shape of the ILIT Perturbation and Response-Extracting the Relaxation Rate Constant, km -- F. Correlating km to Meaningful Physical Parameters -- V. Experimental Implementation of ILIT -- A. The Cell -- B. The Working Electrode: Preparation and Thermal Diffusion Properties -- C. Preparation of Self-Assembled Monolayers -- D. The Electronics -- E. Potential Problems -- F. Energetic and Timing Considerations for Single and Multiple Pulse Experiments -- G. Some Suggested Experimental Protocols -- VI. A Few Examples of Measurements of Interfacial Kinetics -- A. Some Typical Transients -- B. Determining the Value of k° -- C. Arrhenius Plots and Evaluation of ΔH≠ and ΔHλ -- VII. The Potential of the ILIT Approach -- VIII. Some Thoughts About Future Experiments -- IX. Glossary of Terms -- X. Appendix: One-Dimensional Thermal Diffusion into Two Different Phases -- References -- Electrically Conducting Diamond Thin Films: Advanced Electrode Materials For Electrochemical Technologies -- I. Introduction. , II. Diamond Thin Film Deposition, Electrode Architectures, Substrate Materials, and Electrochemical Cells -- III. Electrical Conductivity of Diamond Electrodes -- IV. Characterization of Microcrystalline and Nanocrystalline Diamond Thin Film Electrodes -- V. Basic Electrochemical Properties of Microcrystalline and Nanocrystalline Diamond Thin Film Electrodes -- VI. Factors Affecting Electron Transfer at Diamond Electrodes -- VII. Surface Modification of Diamond Materials and Electrodes -- VIII. Electroanalytical Applications -- A. Azide Detection -- B. Trace Metal Ion Analysis -- C. Nitrite Detection -- D. NADH Detection -- E. Uric Acid Detection -- F. Histamine and Serotonin Detection -- G. Direct Electron Transfer to Heme Peptide and Peroxidase -- H. Cytochrome . Analysis -- I. Carbamate Pesticide Detection -- J. Ferrocene Analysis -- K. Aliphatic Polyamine Detection -- IX. Electrosynthesis and Electrolytic Water Purification -- X. Optically Transparent Electrodes for Spectroelectrochemistry -- XI. Advanced Electrocatalyst Support Materials -- A. Composite Electrode Fabrication and Characterization -- B. Oxygen Reduction Reaction -- C. Methanol Oxidation Reaction -- XII. Conclusions -- References -- Author Index -- Subject Index.

Note: Front Cover -- Contents -- Introduction to the Series -- Contributors to Volume 24 -- Contents of Other Series Volumes -- Chapter 1: Advances in Potentiometry -- Chapter 2: Electrochemistry at Platinum Single Crystal Electrodes -- Chapter 3: Application of SECM to Corrosion Studies -- Chapter 4: Surface Interrogation Mode of Scanning Electrochemical Microscopy (SI-SECM): An Approach to the Study of Adsorption and (Electro)Catalysis at Electrodes -- Back Cover.

Note: Cover -- Half Title -- Title Page -- Copyright Page -- Table of Contents -- Introduction to the Series -- Contributors to Volume 15 -- Contents of Other Volumes -- Electrochemistry of Liquid-Liquid Interfaces -- I. Introduction -- II. Historical Overview of the Physical Chemistry of ITIES -- III. Energy of Transfer and Interfacial Potentials -- IV. Interfacial Thermodynamics -- V. Electrified ITIES -- VI. Charge Transfers Across ITIES -- VII. Concluding Remarks -- Appendix: Electrochemistry of Liquid-Liquid Interface -- References -- Ellipsometry: Principles and Recent Applications in Electrochemistry -- I. Introduction -- II. Specular Reflection of Light from the Solid-Electrolyte -- III. Instrumentation -- IV. Optical Properties of Surface Films in Electrochemical Systems and Their Qualitative Ellipsometric Effects -- V. Experimental Results -- VI. Outlook -- References -- Voltammetry at Ultramicroelectrodes -- I. Introduction -- II. Diffusion at Ultramicroelectrodes -- III. Advantages of Ultramicroelectrodes -- IV. Construction and Use of Ultramicroelectrodes -- References -- Author Index -- Subject Index.

Note: Front cover -- Introduction to the Series -- Content s of Other SeriesVolumes -- Contents -- Contributors to Volume 23 -- Chapter 1. Electrochemistry atLiquid-Liquid Interfaces -- Chapter 2. Reduction of Platinum under Superdry Conditions -- Chapter 3. Impact of Metal-Ligand Bonding Interactions on the Electron-Transfer Chemistry of Transition-Metal Nanoparticles -- Chapter 4. Sol-Gel Electrochemistry -- Index -- Back cover.

Note: Cover -- Half Title -- Title Page -- Copyright Page -- Introduction to the Series -- Contributors to Volume 16 -- Contents of Volume 16 -- Contents of Other Volumes -- Voltammetry Following Nonelectrolytic Preconcentration -- I. Introduction and Scope -- II. Adsorptive Stripping Voltammetry -- III. Voltammetry Following Preconcentration at Chemically Modified Electrodes -- IV. Conclusion -- References -- Hydrodynamic Voltammetry in Continuous-Flow Analysis -- I. Introduction -- II. Background -- III. Electrode Materials -- IV. Analytical Techniques and Applications -- V. Indirect Methods -- VI. New Electrode Systems -- VII. On-line Monitoring and Control -- Glossary of Abbreviations -- References -- Electrochemical Aspects of Low-Dimensional Molecular Solids -- I. Introduction -- II. Description of Low-Dimensional Solids -- III. Redox Properties of Molecular Solids -- IV. Electrochemical Preparation of Low-Dimensional Solids -- V. Low-Dimensional Solids as Electrode Materials -- VI. Summary -- Appendix: Definitions of Acronyms -- References -- Author Index -- Subject Index.

Note: Front Cover -- Contents -- Introduction to the Series -- Contributors to Volume 25 -- Contents of Other Series Volumes -- Chapter 1: Measuring Absolute Single Half-Cell Reduction Potentials with Mass Spectrometry -- Chapter 2: Electrochemistry of Hydrogenases -- Chapter 3: Bioanalytical Applications of Electrochemistry at Liquid-Liquid Microinterfaces -- Chapter 4: Electrolytes Based on Weakly Coordinating Anions: An Advance in Anodic Molecular Electrochemistry -- Back Cover.

Note: Cover -- Contents -- Introduction to the Series -- Contributors to Volume 26 -- Contents of Other Series Volumes -- Chapter 1: Nanoscale Scanning Electrochemical Microscopy -- Chapter 2: Electrochemical Applications of Scanning Ion Conductance Microscopy -- Chapter 3: Electrode Surface Modification Using Diazonium Salts -- Back Cover.

Note: Cover -- Series Page -- Half Title -- Title Page -- Copyright Page -- Introduction to the Series -- Contributors to Volume 17 -- Contents -- Contents of Other Volumes -- APPLICATIONS OF THE QUARTZ CRYSTAL MICROBALANCE TO ELECTROCHEMISTRY -- I. Introduction -- II. Experimental Methods -- III. Monolayer Systems -- IV. Multilayer Deposition and Dissolution -- V. Polymer Films -- VI. Future Applications of the EQMC -- References -- OPTICAL SECOND HARMONIC GENERATION AS AN IN SITU PROBE OF ELECTROCHEMICAL INTERFACES -- I. Introduction -- II. Theoretical Considerations -- III. Experimental Methods -- IV. Experimental Application -- V. Concluding Remarks -- References -- NEW DEVELOPMENTS IN ELECTROCHEMICAL MASS SPECTROSCOPY -- I. Introduction -- II. Experimental Methods -- III. Features and Limitations of On-Line MS Techniques -- IV. Study of Adsorbates and Catalytic Processes -- V. Applications in Batteries, Corrosion, Electrosynthesis, and Water Electrolysis -- VI. Recent Developments -- References -- CARBON ELECTRODES: STRUCTURAL EFFECTS ON ELECTRON TRANSFER KINETICS -- I. Introduction and Scope -- II. Bulk Carbon Structure and Preparation -- III. Structure of Carbon Electrode Surfaces -- IV. Carbon Electrode Preparation and Performance -- V. Conclusions -- References -- Author Index -- Subject Index.

Note: Book Cover -- Title -- Copyright -- Contents.