Electrodynamics 2

Course number: 203-2-4481
3 hours, 3 points

Lecturer: Michael Gedalin

Lectures / Classes / Reception hours:

Day	Time	Building / Room	Comments
Tuesday	17-20	54/207	Lecture
Thursday	10-12	54/326	Reception hours of M. Gedalin

Policy
Forum

Syllabus (from the Shnaton site):

Relativistic electrodynamics (optional)
Radiative processes (optional)
Electrostatics of conductors.
Electrostatics of dielectrics
Magnetic fields and magnetic properties of materials
Magnetohydrodynamics
Electromagnetic waves and radiation processes in media.

Sources and links:

Sources:
- A: Landau, Electrodynamics of continuous media, QC 518.L313 1984
- B:Ginzburg, Applications of electrodynamics in theoretical physics and astrophysics, QC 20.G5313 1989 (or Ginzburg, Theoretical physics and astrophysics)
- C: Pollack & Stump, Electromagnetism, QC 760.P65 2002
- D: Jackson, Classical electrodynamics, QC 631.J3 1999
- E: Landau & Lifshitz, The classical theory of fields, QC 665.E4L3713 1995
- F: Bo Thide, Electromagnetic field theory
Exercises
Lecture notes
Useful links
Gedalin's teaching page

Course structure

No.	Topic	Sources
1	Relativistics electrodynamics (optional):	E.1 (1-7), E.2 (8-9), E.3 (15-25), E.4 (26-33)
2	Radiative processes (optional): bremsstrahlung, cyclotron radiation, radiation of relativistics sources, synchrotron radiation, Hamiltonian approach	F.7.3, F.8, E.9, B(1)
3	Electrostatics of conductors: electrostatic fields, energy, force on conductors, boundary value problems with conductors	A (1-3, 5)
4	Electrostatics of dielectrics polarization and bound charge, permittivity, energy, boundary value problems	C (6.1-6.5), A (6-7, 10, 13-16, 19)
5	Magnetic fields and magnetic properties of materials: magnetization and bound currents, succeptibility, boundary value problems, energy, force, ferromagnetism, superconductivity	C (9.1-9.6), A (29-36), A (53-55)
6	Quasistationary currents and fields: magnetic field penetration into conductor, skin-effect, inductance	A (58-64)
7	Magnetohydrodynamics: conducting fluid in a magnetic field, equilibrium, hyrdomagnetic waves, discontinuities	A (65, 68-72)
8	Macroscopic electrodynamics in simple media: Maxwell equations in media, energy-momentum tensor, generalized dielectric tensor	A (56), G (13)
9	Electromagnetic waves and radiation processes in media I: Hamiltonian approach in media, temporal dispersion, frequency dependence of the permittivity, index of refraction	B (1, 6), A (75-84)
10	Electromagnetic waves and radiation processes in media II: waves in media with temporal and spatial dispersion	B (11)
11	Electromagnetic waves and radiation processes in media III: Cerenkov and Doppler effects, transition radiation	B (7), A (115-116)
12	*Nonlinear electrodynamics (optional): nonlinear effects, self-focusing, second harmonic generation, Raman scattering	A (107-112)

"I never teach my pupils; I only attempt to provide the conditions in which they can learn." Albert Einstein

Electrodynamics 2

Lectures / Classes / Reception hours:

Syllabus (from the Shnaton site):

Sources and links:

Course structure

This page is maintained by Michael Gedalin