Lectures related to Electric Potential and Field Relationship

Capacitor and Self-Heating in a Wire

Covers the simulation of a capacitor and self-heating in a wire using Comsol.

Maxwell's Equations and Induction Phenomenon

Explores Maxwell's equations, induction in moving conductors, electromotive force, and electrical fields.

Comsol Session: Parallel Plate Capacitor

Covers physical models, project groups, and Comsol setup for a parallel plate capacitor.

Electric field and electric potential

Covers electric field, potential, field lines, and potential difference with practical examples.

Atomic Structure: Charge Density and Electric Field

Explains charge density and electric field distribution within an atom.

Electric Fields: Concepts and Calculations

Covers the fundamental concepts of electric fields and their calculations.

Second Maxwell's equation: Magnetic dipole

Covers Maxwell's equations, magnetic dipoles, vector potential, torque, and field patterns.

Electrostatics Fundamentals

Introduces electrostatics fundamentals, covering electric charges, fields, potentials, conductors, and Faraday's cage experiments.

Magnetostatics: Magnetic Field and Force

Covers magnetic fields, Ampère's law, and magnetic dipoles with examples and illustrations.

Electric Field of Dipole Moment

Explores the electric field of a dipole moment and the concept of bound charges in a dielectric.

Comsol: Parallel plate capacitor

Focuses on modeling a parallel plate capacitor using Comsol, emphasizing clear project ideas and group collaboration.

Electric Fields: Fundamentals

Introduces the fundamentals of electric fields, equipotential surfaces, and electric potential calculation.

Calculating Voltage and Capacitance

Covers the calculation of voltage and capacitance using superposition and electric dipoles.

Electric Fields and Gauss's Law

Explores charged particles, electric dipoles, Gauss's law applications, conducting spheres, and the circuital law.

Maxwell's Equations: Capacitors and Magnetic Fields

Covers final exam rules, electromagnetic waves, electric fields, and circuits.

Charge Movement in Electric and Magnetic Fields

Explores charge acceleration, energy conservation, electron-Volt concept, conductor behavior, dielectric materials, and applications in electric and magnetic fields.

Electrostatics: Capacitors and Fields

Explores electrostatics, capacitors, electric fields, potential, and energy calculations in practical exercises.

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Electrostatics: Basis and Applications

Explores Coulomb's law, electric fields, capacitance, conductors, and dielectrics in electrostatic systems.

Electric Fields and Coulomb's Law

Explores Coulomb's Law, electric fields, continuous charge distributions, visualization techniques, and Gauss's Law.