Lectures related to Maxwell's Equations in Materials

Interaction of E-M Waves with Matter: Transmission, Absorption, Reflection

Explores how electromagnetic waves interact with matter, emphasizing transmission, absorption, and reflection.

Maxwell's Equations: Derivation and Implications

Explores the derivation and implications of the 4th Maxwell's equation, emphasizing the importance of charge conservation and the role of displacement current.

Maxwell's Equations and Magnetic Fields

Covers a review of Maxwell's equations and the concepts of internal, demagnetization, and stray fields.

Maxwell's Equations and Induction Phenomenon

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

Lorentz Covariant Formulation: Maxwell Equations

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

Paradoxes with Coulomb's and Ampère's forces. Gauss's Law

Delves into paradoxes with Coulomb's and Ampère's forces, leading to the derivation of Gauss's Law from Maxwell's equations.

Understanding Displacement Vector and Plane Waves

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

Constitutive Relations in Materials

Covers constitutive relations in materials, induced effects, related charges, and non-linear responses.

Optical Properties: Materials & Maxwell's Equations

Explores optical properties of materials, Maxwell's equations, and material response to light.

Electromagnetic Phenomena

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

Chemistry: Atomic Structure and Thermodynamics

Covers atomic structure, thermodynamics, material properties, and ideal gas law.

Cosmological Puzzles: Dark Matter and Energy

Explores fundamental cosmological puzzles related to dark matter and energy.

Magnetostatics: Magnetic Field and Force

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

Intensity: Light, Heat, and Energy Transport

Explores heat generation from light-matter interactions, energy transport through electromagnetic waves, and the concept of intensity.

Electromagnetic Duality

Explores electromagnetic duality, a theorem establishing symmetry in Maxwell's equations for electric and magnetic quantities.

Introduction to Electricity and Magnetism

Covers the basics of electricity and magnetism, from ancient observations to Maxwell's equations and Coulomb's law.

Dispersion Relation in Vacuum

Covers Maxwell's equations, unit systems, Fourier transform, and charge conservation with exercises on wave equations and dispersion relations.

Electromagnetic Fields Overview

Explores product fields by charges, magnetic and electric dipoles, material properties, conductors, dipoles behavior, and Maxwell equations.

Maxwell's Equations in Vacuum (C1-C10)

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

Magnetism: Basics and Phenomena

Explores the basics of magnetism, magnetic fields, and magnetic properties in materials.