Lectures related to Charge Movement in Electric and Magnetic Fields

Maxwell's Equations and Induction Phenomenon

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

Magnetostatics: Magnetic Field and Force

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

Explores charge density, electric field, Coulomb's law, and electric potential relationships, including forces between charges and the dominance of gravitational and electrostatic forces.

Second Maxwell's equation: Magnetic dipole

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

Magnetostatics: Lorentz Force and Magnetic Fields

Explores Lorentz force and magnetic fields interactions with moving charges in stationary magnetic fields.

Electromagnetism and Optics: Forces, Fields, and Optics

Covers the basics of electromagnetism and optics, including forces, fields, and optical principles.

Verlet Scheme: Magnetic Fields and Speed Dependent Forces

Explores the Verlet scheme, magnetic fields, speed-dependent forces, and nonlinear physics through simulations and exercises.

Electric field and electric potential

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

Maxwell's Equations: Capacitors and Magnetic Fields

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

Sources of Magnetic Fields and Induction

Explores the generation of magnetic fields, induction, and practical applications in electromagnetism.

Understanding Displacement Vector and Plane Waves

Explores the displacement vector D, plane waves, and magnetic vector potential, addressing student questions and clarifying key concepts.

Electromagnetism: Fundamentals and Applications

Explores the basics of electromagnetism, Ohm's law, Lenz's law, and Faraday's law, shedding light on electromagnetic devices.

Magnetic Effects in Materials

Explores magnetic effects, dielectric behavior, and properties of ferroelectric and piezoelectric materials.

Magnetic Dipole and Field Analysis

Explores magnetic dipole moment, torque, energy, field analysis, and Maxwell's equations for magnetostatics.

Magnetic Moments and Field Lines: Equivalence and Induction

Explores magnetic dipole, field lines, and induction by moving charges.

Electromagnetic Waves and Lorentz Force

Covers Lorentz force, electromagnetic waves behavior, and wave equations.

Electrostatics Fundamentals

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

Planck Units and Lorentz Transformations

Explores Planck units, Klein-Gordon equation, Lorentz transformations, and Maxwell equations' invariance.

Electromagnetic Forces: Theory and Applications

Covers the theory and applications of electromagnetic forces, including magnetic fields and the movement of charged particles.

Comsol Session: Parallel Plate Capacitor

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