Physics 8110 - Spring 2018 - Electromagnetic Theory II - Syllabus
- Maxwell's displacement current, Maxwell's equations;
- Vector and scalar potentials;
- Gauge transformations, Lorentz gauge, Coulomb gauge;
- Poynting's theorem and conservation of energy for a system of charged particles and electromagnetic fields
- Conservation of linear momentum for a system of charged particles and electromagnetic fields;
- Conservation of angular momentum for a system of charged particles and electromagnetic fields.
- Wave equations for electromagnetic waves
- Plane waves in a non-conducting medium
- Linear and circular polarization
- Reflection and refraction of electromagnetic waves at a plane interface between dielectrics
- Polarization by reflection and total internal reflection
- Waves in a conducting medium
- Superposition of waves in one dimension, group velocity
- Fields at the surface and within a conductor
- Cylindrical cavities and wave guides
- Wave guides
- Modes in rectangular wave guides
- Resonant cavities
- The situation before 1900. Einstein's two postulates
- Lorentz transformations and basic kinematic results of special relativity
- Addition of velocities, four-velocity
- Relativistic momentum and energy of a particle
- Invariance of electric charge, covariance of electrodynamics
- Transformation of electromagnetic fields
- Retarded potentials
- Fields and radiation of a localized oscillating source
- Electric dipole fields and radiation
- Radiation from an arbitrary distribution of charges and currents
- The Lienard-Wiechert potentials
- The field produced by a moving charged particle
- The field produced by a charged particle in uniform motion
- Radiation from an accelerated charged particle at low velocities - Larmor formula
- Radiation from a charged particle with co-linear velocity and acceleration
- Radiation from a charged particle confined to a circular orbit