This note covers the
following topics: Electrostatic energy calculations, Poisson equation and
Green's theorm, Green's functions for cartesian coordinates, Method of images,
Cylindrical and spherical geometries, Multipole analysis of charge
distributions, Dipoles and dielectrics, Magnetostatics, Maxwells equations,
Electromagnetic energy and force, Dynamic dielectric media and their effects,
Radiation from moving charges and Special Theory of Relativity.
This PDF covers the
following topics related to Introduction To Extended Electrodynamics : Basic
Notions and Equations of Classical Electrodynamics, Solutions to Maxwell’s
Equations, Amplitude and Phase, Why and What to Change in Classical
Electrodynamics, Extended Electrodynamics, Vacuum Equations in EED, General
Properties of the Equations and Their Solutions, Nonlinear Solutions.
Description of photon-like objects, Interference, Nonlinearity and
Superposition, Basic equations, The Frobenius Integrability and Dissipation,
Explicit Solutions with Nonzero Currents.
This
PDF covers the following topics related to Electrodynamics :
Electrostatics and Magnetostatics, Vector Calculus, Conservation of Charge and
the Maxwell Equations, Energy and Momentum, Electromagnetic Waves, Potentials
and Gauges, Resultant Potentials and Fields, Relativistic Electrodynamics,
Atmospheric Optics, Pictorializing divergence and curl.
This PDF course
introduces the classical theory of electrodynamics describing the interactions
of charged particles among themselves and with electromagnetic fields
and covers the following topics related to Classical Electrodynamics :
Historical remarks and motivation, Electrostatics, Boundary value problems in
electrostatics, Magnetostatics, Time varying fields and Maxwell’s equations,
Radiation.
Author(s): Professor Konstadinos Sfetsos, Department of
Physics, National and Kapodistrian University of Athens
This set of lecture notes is designed to be used to teach graduate
students in classical electrodynamics. It covers the following topics in detail:
Mathematical Physics, Non Relativistic Electrodynamics and Relativistic
Electrodynamics.
The course
note is a one semester advanced note on Electrodynamics at the M.Sc.
Level. It will start by revising the behaviour of electric and magnetic fields,
in vacuum as well as matter, and casting it in the language of scalar and vector
potentials.
This note covers the
following topics: Point of departure, Relativistic Electromagnetism, Energy - Momentum Tensor,
Solving Maxwell’s Equations and Quantum mechanical effects.
This
note tries to develop a unified approach to the solution of problems in
electrostatics, magnetostatics and electromagnetism. It introduces new concepts,
such as Gauge Invariance and Special Relativity, in electrodynamics. Covered
topics are: Potentials, Electromagentic Waves, Classical Optics from Maxwell's
Equations, Boundary value problems, Radiation and Antenna's, Relativity and
ElectroDynamics