PX263-7.5 Electromagnetic Theory and Optics
Introductory description
The module develops the ideas of first year electricity and magnetism into Maxwell's theory of electromagnetism. Maxwell's equations pulled the various laws (Faraday's law, Ampere's law, Lenz's law, Gauss's law and the "law with no name") into one unified and elegant theory. Establishing a complete theory of electromagnetism has proved to be one the greatest achievements of physics. It was the principal motivation for Einstein to develop special relativity, it has served as the model for subsequent theories of the forces of nature and it has been the basis for all of electronics (radios, telephones, computers, the lot...).
The module shows that Maxwell's equations in free space have time-dependent solutions, which turn out to be the familiar electromagnetic waves (light, radio waves, X-rays etc), and studies their behaviour at material boundaries (Fresnel Equations). The module also covers aspects of optical instruments.
Module aims
The module should study Maxwell's equations and their solutions.
Outline syllabus
This is an indicative module outline only to give an indication of the sort of topics that may be covered. Actual sessions held may differ.
Refresher on vector calculus
Ampere's law, Faraday/Lenz's law, Gauss's law in differential form. Need for the displacement current. Statement of Maxwell's equations.
Maxwell equations in vacuum and in matter. Magnetisation and polarization of materials. Relation of E and P, B and M.
Solutions to Maxwell equations in vacuum. Electromagnetic waves, Poynting vector, intrinsic impedance, polarisation. Boundary conditions. Interfaces between dielectrics, separation into perpendicular and parallel components. Refractive index. Ohm's law. Interface with a metal, skin effect.
Optics: reflection and refraction. Wavefronts at plane and spherical surfaces. Lenses. Basics of optical instruments, resolution.
Learning outcomes
By the end of the module, students should be able to:
- Write down and manipulate Maxwell's equations in integral or differential form and derive the boundary conditions at boundaries between linear isotropic materials
- Derive the plane-wave solutions to Maxwell's equations in free space, dielectrics and ohmic conductors
- Describe the interaction of light with optical materials and explain aspects of geometrical optics
Indicative reading list
Young and Freedman, University Physics 11th Edition
IS Grant and WR Phillips, Electromagnetism
E Hecht, Optics
View reading list on Talis Aspire
Subject specific skills
Knowledge of mathematics and physics. Skills in modelling, reasoning, thinking.
Transferable skills
Analytical, communication, problem-solving, self-study
Study time
Type | Required |
---|---|
Lectures | 18 sessions of 1 hour (72%) |
Other activity | 7 hours (28%) |
Total | 25 hours |
Private study description
Working through lecture notes, solving problems, wider reading, discussing with others taking the module, revising for exam, practising on past exam papers
Other activity description
7 problem classes
Costs
No further costs have been identified for this module.
You do not need to pass all assessment components to pass the module.
Assessment group D3
Weighting | Study time | Eligible for self-certification | |
---|---|---|---|
Coursework | 15% | No | |
Assessed work as specified by department |
|||
On-campus Examination | 85% | No | |
Answer 2 questions
|
Assessment group R2
Weighting | Study time | Eligible for self-certification | |
---|---|---|---|
On-campus Examination - Resit | 100% | No | |
Answer 2 questions
|
Feedback on assessment
Personal tutor, group feedback
Courses
This module is Core for:
- Year 2 of UPXA-FG33 Undergraduate Mathematics and Physics (BSc MMathPhys)