## Electrochemical methods: fundamentals and applicationsTakes 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. |

### Dall'interno del libro

Risultati 1-3 di 89

Pagina 237

the experimental /(/) data, is denned as I(t), then

which represent the integral in

transformation technique; clearly the convolutive (15) and semi- integral (16, 17)

...

the experimental /(/) data, is denned as I(t), then

**equation**6.7.1 becomes (15) ...which represent the integral in

**equation**6.7.3, have been used in discussing thistransformation technique; clearly the convolutive (15) and semi- integral (16, 17)

...

Pagina 282

The variation of Ct with time is given by f^ = -V.Jy = divJ, (8.2.4) By combining (8.2

.1) and (8.2.4), assuming that migration is absent and that D, is not a function of x,

y, and z, we obtain the general convective-diffusion

The variation of Ct with time is given by f^ = -V.Jy = divJ, (8.2.4) By combining (8.2

.1) and (8.2.4), assuming that migration is absent and that D, is not a function of x,

y, and z, we obtain the general convective-diffusion

**equation**: ^ = D^C, " v-VC, ...Pagina 713

in potential step experiments, 173 Navier-Stokes

layer, 32 Nernst

ac ...

in potential step experiments, 173 Navier-Stokes

**equation**, 282 Neinst diffusionlayer, 32 Nernst

**equation**, 51, 62 kinetic derivation of, 100 Nernst-Planck**equation**, 27, 120 Nernstian reaction, definition, 29 Nernstian waves, 29 et seq.ac ...

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### Indice

Potentials and Thermodynamics of Cells | 44 |

Kinetics of Electrode Reactions | 104 |

Mass Transfer by Migration and Diffusion | 119 |

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Electrochemical Methods: Fundamentals and Applications Allen J. Bard,Larry R. Faulkner Anteprima non disponibile - 2000 |

### Parole e frasi comuni

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