Concept

Electrochemical cell

Related lectures (30)

Electrochemistry: Principles and Applications in Thermodynamics

Introduces electrochemistry, covering electrochemical potential, oxidation-reduction reactions, and practical applications in thermodynamics.

Chemical Equilibria and Reactivity

Explores chemical equilibria, reactivity, redox reactions, and galvanic cells.

Electrochemistry Fundamentals

Covers the fundamentals of electrochemistry, focusing on cell potential, current production, and the relationship between current and reactant conversion.

Osmotic Pressure: Electrochemical Potential

Explores osmotic pressure and electrochemical potential, highlighting their calculation and significance in electrolyte behavior.

Electrochemical Cell: pH Calculation

Covers the calculation of pH in an electrochemical cell scenario involving copper and hydrogen electrodes.

Electrochemistry Fundamentals

Delves into concentration cells, solubility products, half-cell potentials, and electrochemical applications, including corrosion prevention and fuel cells.

Galvanic Cells: Standard Potentials and Concentration Effects

Explores galvanic cells, standard potentials, concentration effects, equilibrium constants, and pH meters in concentration cells.

Enzymes' based Biosensors

Explores enzymes' based biosensors, redox reactions, sensitivity in biosensors, and the detection of hydrogen peroxide.

Electrochemistry Fundamentals

Delves into concentration cells, solubility products, half-cell potentials, and practical electrochemistry applications, including electrolysis and corrosion prevention.

Neural Electrodes: Stimulation and Safety

Explores neural stimulation with electrodes, discussing current flow effects, charge injection challenges, and electrode material properties.

Electrode Polarization and Tissue Damage

Explores electrode polarization, tissue damage causes, and avoidance methods, including biphasic pulses and interface modeling.

Redox Reactions: Balancing Equations and Oxidation States

Explores redox reactions, balancing equations, oxidation states, and electrode roles.

Electrochemistry: Redox Reactions and Cell Potential

Explores electrochemistry, emphasizing redox reactions and cell potential in galvanic cells, Nernst and Faraday's laws, and their applications in electrolysis and fuel cells.

CO2 Reduction by FeNi-CODH

Explores the proposed mechanism of CO2 reduction by FeNi-CODH and the selective 2-electron CO2 reduction to CO, highlighting the role of hydrogen bonding.

Circuits for Amperometric Detection

Explores amperometric detection principles, focusing on DNA indirect detection through redox reactions.

Marcus Theory: Reorganization Energy

Delves into the Marcus Theory, emphasizing reorganization energy in electrochemical reactions and its practical implications.

Electrochemical Cells: Redox Reactions and CV Technique

Covers redox reactions, cyclic voltammetry, and electrochemical cell design for drug detection.

CMOS Circuits: Metabolites Detection

Explores CMOS circuits for metabolites detection in fixed-voltage cells, covering operational amplifier features, saturation risks, temperature compensation, and current measurement techniques.

Electrochemical Cells: Redox Reactions and Standard Potentials

Explores electrochemical cells, redox reactions, and standard potentials in depth.

Chemical Equilibria and Reactivity

Explores chemical equilibria, redox reactions, Nernst equation, electrochemical cells, pH influence, and membrane potential.