Undergraduate Course: Foundations of Electromagnetism (PHYS09050)

Course Outline
School	School of Physics and Astronomy	College	College of Science and Engineering
Course type	Standard	Availability	Available to all students
Credit level (Normal year taken)	SCQF Level 9 (Year 3 Undergraduate)	Credits	10
Home subject area	Undergraduate (School of Physics and Astronomy)	Other subject area	None
Course website	None	Taught in Gaelic?	No
Course description	This is a one-semester course, covering time-independent and time-dependent properties of electric and magnetic fields leading to the vector calculus formulation of Maxwell's Equations and the derivation of electro-magnetic waves in vacuo and in media.

Entry Requirements (not applicable to Visiting Students)
Pre-requisites	Students MUST have passed: Dynamics and Vector Calculus (PHYS08043)	Co-requisites
Prohibited Combinations	Students MUST NOT also be taking Electromagnetism (PHYS09060)	Other requirements	None
Additional Costs	None

Information for Visiting Students
Pre-requisites	None
Displayed in Visiting Students Prospectus?	No

Course Delivery Information

Delivery period: 2013/14 Semester 1, Available to all students (SV1)			Learn enabled: No	Quota: None
Web Timetable	Web Timetable
Course Start Date	16/09/2013
Breakdown of Learning and Teaching activities (Further Info)	Total Hours: 100 ( Lecture Hours 22, Seminar/Tutorial Hours 22, Revision Session Hours 1, Programme Level Learning and Teaching Hours 2, Directed Learning and Independent Learning Hours 53 )
Additional Notes
Breakdown of Assessment Methods (Further Info)	Written Exam 80 %, Coursework 20 %, Practical Exam 0 %
Exam Information
Exam Diet	Paper Name	Hours:Minutes
Main Exam Diet S2 (April/May)	Foundations of Electromagnetism (PHYS09050)	2:00

Delivery period: 2013/14 Semester 1, Part-year visiting students only (VV1)			Learn enabled: No	Quota: None
Web Timetable	Web Timetable
Course Start Date	16/09/2013
Breakdown of Learning and Teaching activities (Further Info)	Total Hours: 100 ( Lecture Hours 22, Seminar/Tutorial Hours 22, Revision Session Hours 1, Programme Level Learning and Teaching Hours 2, Directed Learning and Independent Learning Hours 53 )
Additional Notes
Breakdown of Assessment Methods (Further Info)	Written Exam 80 %, Coursework 20 %, Practical Exam 0 %
Exam Information
Exam Diet	Paper Name	Hours:Minutes
Main Exam Diet S1 (December)		2:00

Summary of Intended Learning Outcomes
Upon successful completion of this course it is intended that a student will be able to: 1)State the integral laws of electromagnetism and state and derive Maxwell's equations for charges and currents in a vacuum 2)Define and explain charge and current densities (in bulk and on surfaces and lines), and conductivity 3)Define, and use the concepts of electric and magnetic dipoles; calculate the fields from dipoles and forces and torques on them 4)Define and explain: polarisation and magnetisation; the fields D, H, E and B; the relation between E, B and the force on a particle; polarisation charges and magnetisation currents; boundary conditions on fields at interfaces between media; Maxwell's equations in media 5)Define and explain in atomic terms: the response of linear media; relative permittivity and permeability; their relation to the electromagnetic energy density; nonlinear media such as ferromagnets 6)Formulate and solve boundary-value problems using: superposition methods; uniqueness principles; the method of images; qualitative reasoning based on field lines; the equations of Biot-Savart, Faraday, Ampere, Gauss, Laplace and Poisson 7)Formulate and solve with vector calculus problems of static and time-varying electrical and magnetic fields 8)Derive and apply the concepts of: Maxwell's displacement current; the continuity equation; self- and mutual inductance; Poynting's vector; energy flux; radiation pressure 9)Derive and explain electromagnetic radiation using plane-wave solutions of Maxwell's equations; apply these to problems of intrinsic impedance, attenuation, dispersion, reflection, transmission, evanescence, and the skin effect in conductors; derive and explain total internal reflection, polarisation by reflection. 10)Explain and utilise the properties of the electric scalar potential and the magnetic vector potential.

Assessment Information
Coursework 20%, examination 80%.

Special Arrangements
None

Additional Information
Academic description	Not entered
Syllabus	- Integral and differential forms of Gauss's Law. Examples of 1D, 2D, 3D charge distributions. - Potential. Poisson's Equation. Calculation of electric fields. - Uniqueness theorem. Solution of electrostatic problems. Method of images. - Dipole field. Quadrupole field. Multipole expansion. - Electrostatic boundaries. Polarisation in dielectrics. Surface charges. - Biot-Savart Law. Magnetic vector potential. Calculation of magnetic fields. - Integral and differential forms of Ampere's Law. Examples of 1D, 2D current distributions. - Magnetostatic boundaries. Magnetisation. Surface currents. - Time-varying fields. Faraday's Law. Induction. - Calculation of self and mutual inductance. - Displacement current. Maxwell's equations and their solution in vacuo. - Introduction to Electromagnetic waves. - Solution of Maxwell's equations in dielectrics. - Continuity theorem. Conservation laws - Poynting vector. Energy storage & transport by waves.
Transferable skills	Not entered
Reading list	Not entered
Study Abroad	Not entered
Study Pattern	Not entered
Keywords	FEMag

Contacts
Course organiser	Prof Martin Evans Tel: (0131 6)50 5294 Email: M.Evans@ed.ac.uk	Course secretary	Miss Jillian Bainbridge Tel: (0131 6)50 7218 Email: J.Bainbridge@ed.ac.uk