Gwybodaeth Modiwlau

This module deepens the student's understanding of the empirical laws of electromagnetism. These are expressed in terms of the vector calculus notation introduced earlier in MP26020(FG26020). Problem solving skills are developed where the student is expected to identify and use relevant methods to solve broadly-defined examples in electricity and magnetism. It is a core module for physics degree schemes and provides a background in electricity and magnetism required for modules at higher level.

The module considers the physical laws in electricity and magnetism. The first part focuses on electricity and includes electrostatics and dielectrics with the second part covering magnetic fields, magnetic material and electromagnetic induction. Electromagnetic boundary conditions which apply at the interface between two simple media are discussed. The physical laws are expressed in terms of the differential operators of vector calculus and collectively presented as Maxwell's equations.

RECAP VECTOR CALCULUS
- grad, div, curl
- divergence theorem, Stokes' theorem
- vector identities

ELECTROSTATICS
- electric charge and field
- Gauss' law
- electrostatic energy, potential
- capacitors, dielectrics, polarisation, electric displacement, Gauss’ law for electric displacement
- boundary conditions for D and E
- Poisson's equation
- electrostatic calculations

MAGNETIC FIELDS
- Lorentz force
- magnetic dipole
- Ampere's law, Biot-Savart law, magnetic vector potential
- magnetisation, magnetic intensity
- boundary conditions for B and H
- magnetic hysteresis

ELECTROMAGNTIC INDUCTION
- Faraday's law, Lenz's law
- inductance
- magnetic energy

MAXWELL EQUATIONS
- equation of continuity
- displacement current
- Maxwell's equations and plane electromagnetic wave solution
- Poynting vector
- polarisation of waves, behaviour at plane interfaces