This note explains the following topics: Nonfaradaic processes and
electrode-solution interface, Faradaic processes and rates of electrode
reactions, Mass-transfer controlled reactions, Basic Electrochemical
Thermodynamics, Electrochemical potential, Liquid junction potential, Selective
electrodes, Essentials of electrode reactions, Butler-Volmer model of electrode
kinetics, Implications of Butler-Volmer model for 1-step, 1-e process, Mass
transfer equation, Mixed migration and diffusion near an electrode,
Sampled-current voltammetry for quasireversible and irreversible electrode
reactions, Nernstian systems, Totally irreversible systems, Quasireversible
systems and Cyclic voltammetry.
This
lecture note contains the following topics: introduction to Electrochemistry, Electrochemistry
Question bank, Corrosion and electrochemical process, Batteries and fuel cells,
Advanced materials, Nano materials and laboratory manual.
This note explains the following topics: Basic concepts for
electrochemistry, Electric charge and current, Electrical quantities and their
SI units, Potential and Thermodynamics, Principles of electrochemistry,
Electroactive layers and modified electrodes, Electrochemical responses of
adsorbed monolayers, Photoelectrochemistry, Scanning probe techniques,
Spectroelectrochemistry, Scanning probe techniques, Vibration spectroscopy.
This book presents the link between the exposed method and its
applications in a very explicit manner and offers a wide range of practical
examples. The book provides not only a vision of actual methods but also their
necessary further improvements and suggested developments.
This note explains the following topics: Nonfaradaic processes and
electrode-solution interface, Faradaic processes and rates of electrode
reactions, Mass-transfer controlled reactions, Basic Electrochemical
Thermodynamics, Electrochemical potential, Liquid junction potential, Selective
electrodes, Essentials of electrode reactions, Butler-Volmer model of electrode
kinetics, Implications of Butler-Volmer model for 1-step, 1-e process, Mass
transfer equation, Mixed migration and diffusion near an electrode,
Sampled-current voltammetry for quasireversible and irreversible electrode
reactions, Nernstian systems, Totally irreversible systems, Quasireversible
systems and Cyclic voltammetry.
This note explains the
theory behind fundamental electrochemical processes and also covers design,
perform, troubleshoot, and analyze electrochemical experiments.
Electrochemistry
has been undergoing significant transformations in the last few decades. It is
now the province of academics interested only in measuring thermodynamic
properties of solutions and of industrialists using electrolysis or
manufacturing batteries, with a huge gap between them. Topics covered includes:
Chromatographic, Polarographic and Ion-Selective Electrodes Methods for Chemical
Analysis of Groundwater, Electron Beam Ablation Phenomenon, Oxidation Chemistry
of Metal, Membrane Electrochemistry, Electroanalytical Sensor Technology.
This note introduces principles
and mathematical models of electrochemical energy conversion and storage.Topics
covered includes: equivalent circuits, thermodynamics, reaction kinetics,
transport phenomena, electrostatics, porous media, and phase transformations, applications to batteries, fuel cells,
supercapacitors, and electrokinetics.
Edited by Currently the research field of electrochemical cells is a
hotspot for scientists and engineers working in advanced frontlines of micro-,
nano- and bio-technologies, especially for improving our systems of energy
generation and conversation, health care, and environmental protection. With the
efforts from the authors and readers, the theoretical and practical development
will continue to be advanced and expanded.
This note covers the following topics:
Galvanic cells and electrodes, Cell potentials and thermodynamics, The Nernst
Equation, Applications of the Nernst Equation, Electrochemical energy storage
and conversion, Electrolytic cells and electrolysis.
This note covers
the following topics: Electrochemical cells, Prediction and significance of cell
potentials, The Nernst equation, Batteries and fuel cells, Electrochemical
Corrosion, Electrolytic cells.
Author(s): Stephen K. Lower, Simon Fraser University