Explores the working principles of fuel cells, covering chemical reactions, electrode surfaces, materials, thermodynamics, kinetics, and efficiency.
Explores potential step methods, CV curves, energy storage devices, water-splitting, microbial fuel cells, batteries, capacitors, and Li-ion battery design.
Covers the fundamentals of electrochemistry, focusing on cell potential, current production, and the relationship between current and reactant conversion.
Explains the Butler-Volmer equation, exchange current density, and electrode reaction kinetics.
Delves into electrochemical kinetics, covering fuel cells, Butler-Volmer equation, current-voltage curves, and charge transfer resistance.
Explores electrochemical reactions, including electrolysis of NaCl, anodic and cathodic reactions, production rates, and current efficiency.
Explores the Butler-Volmer model, electrode surface region, electric double layer, multi-step mechanisms, Marcus theory, and electron tunneling.
Explores Electron Transfer Theory, covering electron tunneling, the Gerischer model, and charge transfer.
Explores mass transfer in electrochemistry, covering diffusion, migration, convection, Nernst Planck equation, linear diffusion approximations, and transient response.
Delves into redox systems, current-potential relationships, standard reduction potentials, and electrode behavior.
