Lectures related to Dipolar Radiation and Larmor Formula

Explores electromagnetic fields in a medium, focusing on macroscopic and microscopic fields and their sources.

Introduces the importance of studying electromagnetic phenomena and Maxwell's equations.

Explores electromagnetic field theory, current densities, Kirchhoff's law, and complex phasors in Maxwell's equations.

Covers the Gupta-Bleuler quantization method in Quantum Field Theory, focusing on redundancy in the electromagnetic field and the recovery of Maxwell equations.

EM Field: Quantum Field Theory II

Covers the electromagnetic (EM) field in Quantum Field Theory II, discussing gauge transformations, symmetry principles, and field quantization.

Quantum Field Theory II: EM Field and Particle States

Covers the EM field and particle states in quantum field theory.

Maxwell Equations: Lecture 12

Covers Maxwell's equations and the relationship between magnetic induction and electric field.

Cosmological Puzzles: Dark Matter and Energy

Explores fundamental cosmological puzzles related to dark matter and energy.

General Physics: Quantum - Black Body Radiation and Planck Theory

Explores black body radiation, Planck theory, classical physics limitations, and electromagnetic density.

Introduction to Electromagnetism

Covers the nature of electromagnetic waves, including plane waves and photons, their wavelength, period, and dispersion relationship, and the electromagnetic spectrum.

Electromagnetic Fields Interface Conditions

Covers interface conditions for electromagnetic fields between two media and linear isotropic medium properties.

Uniqueness of Electromagnetic Field

Delves into the conditions for the uniqueness of solutions to Maxwell's equations in different media and sources, emphasizing the role of boundary conditions and material losses.

Electromagnetic Waves: Wave Equation and Maxwell's Equations

Explores the wave equation for electromagnetic waves, Maxwell's predictions, and the importance of polarization in defining wave properties.

Magnetic Field and Vector Potential: Relation with Current, Galvanometer, and Maxwell's Equations

Explores the relationship between magnetic field and vector potential, discussing galvanometers and Maxwell's equations.

Validation of Computational Electromagnetics

Explores the challenges in validating computational electromagnetics, emphasizing the importance of reliability functions and techniques for verification and validation.

Electromagnetic waves

Explores the wave equation for electromagnetic fields, the propagation of electromagnetic waves, the fundamental velocity of light, and the concept of polarization.

Theory of Images and Equivalence Principle

Explores the theory of images, equivalence principle, conductors, duality, and uniqueness in electromagnetism with practical examples.

Quantum Mechanics: Maxwell Equations

Covers the application of Maxwell's equations in quantum mechanics.

Relativistic Motion of Charged Particles

Explores the relativistic motion of charged particles in electric fields, focusing on Lorentz covariant electrodynamics and the relativistic Larmor power.

Lorentz Covariant Formulation: Maxwell Equations

Covers Lorentz transformations, Maxwell equations, and charge conservation in Lorentz invariant physics.