Electrochemical methods: fundamentals and applications
Takes the student from the most basic chemical and physical principles through fundamentals of thermodynamics, kinetics, and mass transfer, to a thorough treatment of all important experimental methods. Treats application of electrochemical methods to elucidation of reaction mechanisms; double layer structure and surface processes, and their effects on electrode processes are developed from first principles; other key features include a chapter on operational amplifier circuits and electrochemical instrumentation, unique coverage of spectrometric and photochemical experiments, and Laplace transform and digital simulation techniques. Contains numerous examples, illustrations, end-of-chapter problems, references, uniform mathematical notation, and an extensive list of symbols, abbreviations, definitions, and dimensions.
55 pagine corrispondenti a metal in questo libro
Risultati 1-3 di 55
Cosa dicono le persone - Scrivi una recensione
Nessuna recensione trovata nei soliti posti.
Potentials and Thermodynamics of Cells
Kinetics of Electrode Reactions
Mass Transfer by Migration and Diffusion
5 sezioni non visualizzate
Altre edizioni - Visualizza tutto
Electrochemical Methods: Fundamentals and Applications, 2nd Edition
Allen J. Bard,Larry R. Faulkner
Anteprima limitata - 2000
A. J. Bard adsorbed adsorption American Chemical Society Anal anodic anthracene applied behavior boundary conditions bulk capacitance cathodic cell cell potential charge transfer Chem circuit cm/sec coefficient complex components consider controlled coulometric current-potential cyclic cyclic voltammetry density derived differential diffusion layer disk double-layer drop effect electrochemical electrochemical cell Electrochemistry electrode potential electrode processes electrode reaction electrode surface electrolysis electron transfer equation equilibrium example experiment experimental faradaic free energy frequency function given hence i-E curve impedance interface involving kinetic limiting current linear mass transfer measurements metal methods Nernst equation nernstian obtained overpotential oxidation parameters peak phase platinum plot polarography potential step potentiostat problem pulse rate constant redox reduction reference electrode region Reprinted with permission reversible Section semiconductor shown in Figure simulation solution surface concentrations techniques titration totally irreversible transfer reaction transform treatment usually voltage voltammetry voltammogram wave yields zero