Lecture

DLVO Theory and Electrochemistry

Related lectures (32)

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

Colloid Stability: DLVO Theory and Membrane Potential

Explores the DLVO theory and membrane potential to understand colloid stability and forces between charged surfaces.

Dynamic Electrochemistry: Butler-Volmer Equation

Explores the Butler-Volmer equation and its role in electrochemistry applications.

Chemical Equilibria and Reactivity

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

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.

Electrochemistry: Redox Reactions and Cell Potentials

Covers redox reactions, cell potentials, and electrochemical cells in electrochemistry.

Membrane potential: Cellular mechanisms

Explains membrane potential, equilibrium potentials, and ion conductances' role in determining the membrane potential.

Electrochemistry Fundamentals

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

Electrochemistry Fundamentals

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

Neural Cell Membrane Dynamics

Explores neural cell membrane dynamics, including ion channels, action potentials, myelination, and bioelectronic interfaces.

Neural Signals: Properties and Mechanisms

Explores neural signals, nerve properties, neuron building blocks, and resting potential mechanisms.

Modeling the electrical activity of the neuron

Explores the modeling of neuron electrical activity, including ion channels and concentrations, Nernst equation, and resting potential.

Membrane Potential: Electrical Properties of Neurons

Covers membrane potential, its measurement, and the equations governing ionic movement in neurons.

Neurophysiological Data Analysis

Covers neurophysiological data analysis, including AP detection, firing rate computation, and spectral analysis, with a focus on predicting cell classes.

Biopotential Generation: Neuron and Resting Potential

Explores biopotential generation, neuron structure, resting potential, and membrane properties.

Chemical Equilibria and Reactivity

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

Electrochemistry: Redox Reactions

Explores electrochemistry principles, redox reactions, standard potential, and electrolysis applications.

Neural Signals: Properties and Recordings

Explores the mechanical and electrical properties of neural tissues, including the brain and spinal cord, as well as the recording of neural signals using various techniques.

Solar Energy Conversion Devices

Explores solar energy conversion devices, electrochemistry, efficiency calculations, and mass transfer modes in solar energy systems.

Reversal potential and Nernst equation

Explores the reversal potential and Nernst equation in computational neuroscience, focusing on ion channels and neuron biophysics.