PHY3054	Electromagnetism II (IS)	2013-14
	Prof. J.R. Sambles
Delivery Weeks:	T1:01-11
Level:	6 (NQF)
Credits:	15 NICATS / 7.5 ECTS
Enrolment:	4 students (approx)

Description

This module is an Independent Study version of PHY3051. It is taken by students remote from Exeter, e.g. at Stage 3 of F304, who are therefore unable to attend traditional lectures and tutorials.

This is the second electromagnetism module taken by Physics students. It builds on PHY2021 (Electromagnetism I) and covers fundamental physics that students are capable of directly observing. The dielectric and magnetic properties of solids are introduced and a range of interesting phenomena are covered including the scattering of light the propagation of electromagnetic waves, etc., are important in a wide variety of areas and in many key technologies. The early part of the module is primarily a recap and a reinforcing of the difficult material treated at the end of PHY2021.

Module Aims

The module aims to develop students' understanding of Maxwell's equations and their applications including some advanced topics. Specifically, students will get to the point where they can handle the fundamentals of fields due to moving charges and also to begin to explore the interaction of electromagnetic radiation with matter.

Intended Learning Outcomes (ILOs)

A student who has passed this module should be able to:

• Module Specific Skills and Knowledge:
  1. describe all the fundamental aspects of electromagnetism;
  2. explain and solve problems involving the magnetic properties of materials;
  3. explain and solve problems involving the dielectric properties of materials;
  4. explain many aspects of the interaction of electromagnetic radiation with matter;
  5. calculate the effect of such interactions using appropriate vector mathematics;
  6. calculate the fields of moving charges;
  7. solve problems requiring application of Maxwell's equations to a variety of situations as outlined in the syllabus below;
• Discipline Specific Skills and Knowledge:
  8. use vector analysis to solve problems in science and engineering;
• Personal and Key Transferable / Employment Skills and Knowledge:
  9. develop and present a coherent solution to a problem;
  10. self-evaluate, check and correct solutions to problems.

Syllabus Plan

1. Maxwell's Equations
   1. The equation of continuity, displacement-current density
   2. Maxwell's equations for the electromagnetic field, constitutive equations
2. Dielectric Properties of Matter
   1. Classical description of atomic polarisability
   2. Dielectrics, paraelectrics and ferroelectrics: general concepts
   3. P–E loops
3. Magnetic Properties of Matter
   1. Classical model of atomic diamagnetism
   2. Diamagnetism, paramagnetism and ferromagnetics: general concepts
   3. Langevin (classical) theory of paramagnetism and electron paramagnetism in metals
   4. M–B loops, and demagnetisation factors
4. Electromagnetic Waves
   1. Electromagnetic waves in free space
   2. Plane waves and polarization
   3. Plane waves in free space and in isotropic insulating media, dispersion
   4. Energy and momentum in electromagnetic waves; Poynting vector
   5. Plane waves in conductors and the skin effect, waves in plasmas
5. Transmission Lines and Waveguides
6. Fields Produced by Moving Charges
   1. Lienard-Weichert potentials
   2. Fields of a uniformly moving point charge
7. The emission of Radiation
   1. Radiation from an oscillating dipole
   2. Radiation from a set of moving charges
8. Interaction of Radiation with Matter
   1. Fresnel's equations and their optical consequences
   2. Scattering
   3. Metamaterials

Learning and Teaching

Learning Activities and Teaching Methods

Description	Study time	KIS type
5×6-hour self-study packages	30 hours	GIS
4×4-hour problem sets	16 hours	GIS
Reading, private study and revision	104 hours	GIS

Assessment

Weight	Form	Size	When	ILOS assessed	Feedback
0%	Guided self-study	5×6-hour packages	Fortnightly	1-10	Self-evaluation
0%	4 × Problems sets (marked by module convener)	4 hours per set	Fortnightly	1-10	Written
100%	Final Examination	2 hours 30 minutes	January	1-10	Mark via MyExeter, collective feedback via ELE and solutions.

Resources

The following list is offered as an indication of the type & level of information that students are expected to consult. Further guidance will be provided by the Module Instructor(s).

Core text:

• Griffiths D.J. (1999), Introduction to Electrodynamics (3^rd edition), Prentice Hall, ISBN 0-13-805326-X (UL: 537 GRI)

Supplementary texts:

• Kittel C. (2005), Introduction to Solid State Physics (8^th edition), Wiley, ISBN 978-0-471-41526-8 (UL: 530.41 KIT)
• Reitz J.R., Milford F.J. and Christy R.W. (1993), Foundations of Electromagnetic Theory (4^th edition), Addison-Wesley, ISBN 0-201-52624-7 (UL: 530.141 REI)

ELE:

• http://newton.ex.ac.uk/redirects/ELE/phy3054

Further Information

Prior Knowledge Requirements

Pre-requisite Modules	Electromagnetism I (PHY2021)
Co-requisite Modules	none

Re-assessment

Re-assessment is not available except when required by referral or deferral.

Original form of assessment	Form of re-assessment	ILOs re-assessed	Time scale for re-assessment
Whole module	Written examination (100%)	1-10	August/September assessment period

Notes: See Physics Assessment Conventions.

KIS Data Summary

Learning activities and teaching methods SLT - scheduled learning & teaching activities 0 hrs GIS - guided independent study 150 hrs PLS - placement/study abroad 0 hrs Total 150 hrs

Summative assessment Coursework 0% Written exams 100% Practical exams 0% Total 100%

Miscellaneous

IoP Accreditation Checklist	EM-04 Maxwell's equations and plane electromagnetic wave solution; Poynting vector SS-07 Magnetic properties of matter EM-06 Polarisation of waves and behaviour at plane interfaces
Availability	unrestricted
Distance learning	YES (see PHY3051)
Keywords	Physics; Maxwell's equations; Electromagnetic fields; Waves; Radiation; Properties of matter.
Created	01-Oct-10
Revised	N/A