This lecture note
explains the following topics: Maxwell Equations, Outward flux of a general
vector, CURL - Stoke’s Theorem, Equation of continuity, Electrostatics,
Coulomb’s Law, Electric Field, Electric Dipole, Gauss’s Law, Electrostatics in a
dielectric medium, Polar dielectrics, Magnetostatics, Magnetic Media, Surface
Magnetisation Current Density, Diamagnetic Media, Electromagnetic Waves.

This lecture note explains
the following topics: Electric Charge and Force, Electric Field and Simple
Distributions of Charge, Complex Distributions of Electric Charge, The Motion of
Electric Charge, Potential and the Storage of Energy, Capacitors, Electric
Current, Resistance to Electric Current, Magnetic Force, Magnetic Force between
Currents, Magnetic Dipole Moment, Magnetic Induction, Reflection and
Refraction.

This note explains the following topics:
The Bohr-van Leeuwen theorem, The electron spin and magnetic moment, ipole-dipole
interaction, Magnetism of free atoms and ions, Magnetic ions in crystals,
Exchange interactions between local spins, The Heisenberg model, Mean-field
theory for magnetic insulators, The paramagnetic phase of magnetic insulators,
Excitations in the ordered state: magnons and spinons, Paramagnetism and
diamagnetism of metals, Magnetic order in metals.

This lecture note
explains the following topics: Maxwell Equations, Outward flux of a general
vector, CURL - Stoke’s Theorem, Equation of continuity, Electrostatics,
Coulomb’s Law, Electric Field, Electric Dipole, Gauss’s Law, Electrostatics in a
dielectric medium, Polar dielectrics, Magnetostatics, Magnetic Media, Surface
Magnetisation Current Density, Diamagnetic Media, Electromagnetic Waves.

This note gives an
introduction on quantum mechanical view on magnetism in real materials,
especially, consisting of transition metal elements and their compounds, and the
physical principles for the applications of magnetic materials as magnetic
sensors and memory devices.

This book
explains the following topics: Electricity and the Atom, The Nucleus, Circuits,
Fields of Force, Electromagnetism, A Capacitance and Inductance.

This lecture note covers the
following topics: Coulomb's law, superposition, energy of a system of charges,
Basic field concept, flux, Gauss's law, Fields and potentials around conductors,
the electrostatic uniqueness theorem,RC circuits, Thevenin equivalence, Forces
and fields in special relativity. Equivalence of the electric and magnetic
forces, RL circuits, undriven RLC circuits, Wave equation and radiation,Magnetic
fields and materials.

The class note introduces
Maxwell's equations, in both differential and integral form, along with
electrostatic and magnetic vector potential, and the properties of dielectrics
and magnetic materials.

Topics
covered include: Electric and magnetic field and potential; introduction to
special relativity; Maxwell's equations, in both differential and integral form;
and properties of dielectrics and magnetic materials.

This note covers the following topics: electric
fields, electric potential, capacitors, circuits, magnetic fields and forces,
creating magnetic fields, Faraday's law, oscillating circuits, Maxwell's
equations, electromagnetic waves and nature of light.

Author(s): Prof. Walter Lewin, Prof. John Belcher
and Dr. Peter Dourmashkin