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DEGREE REGULATIONS & PROGRAMMES OF STUDY 2015/2016

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DRPS : Course Catalogue : School of Physics and Astronomy : Undergraduate (School of Physics and Astronomy)

Undergraduate Course: Electromagnetism (PHYS09060)

Course Outline
School	School of Physics and Astronomy	College	College of Science and Engineering
Credit level (Normal year taken)	SCQF Level 9 (Year 3 Undergraduate)	Availability	Available to all students
SCQF Credits	20	ECTS Credits	10
Summary	This is a two-semester course, the first 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. The second semester covers the electromagnetic properties of waves including propagation, polarisation, interference and diffraction with example from radio wave, optics and x-ray diffraction.
Course description	Electromagnetism (20 lectures) - 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. Electromagnetic Waves & Optics (20 lectures) - Reflection & transmission of waves at boundaries. - Polarisation states. Polarisers. Malus's Law. Measurement of polarisation. - Derivation of Fresnel Equations. Brewster's angle. - Interference. Double slits. Newton's rings. Michelson/Twyman-Green interferometers. - Multi-beam interference. Fabry-Perot. Anti-reflection coatings. Dielectric stacks. - Single slit diffraction. Diffraction grating. Applications in spectroscopy. X-ray diffraction. - Diffraction from circular aperture. Resolution limit. Aberrations. - Dispersion of Electromagnetic waves. Ionosphere. - Waves in conductors. Absorption. Skin depth. - Waveguides & Cavities. - Coherence. Lasers. - Basic Fourier optics. Optical transfer function. Concept of spatial frequency.

Entry Requirements (not applicable to Visiting Students)
Pre-requisites	Students MUST have passed: Dynamics and Vector Calculus (PHYS08043) AND Physics of Fields and Matter (PHYS08046)	Co-requisites
Prohibited Combinations	Students MUST NOT also be taking Electromagnetism and Relativity (PHYS10093)	Other requirements	None
Additional Costs	None

Information for Visiting Students
Pre-requisites	None
High Demand Course?	Yes

Course Delivery Information

Academic year 2015/16, Available to all students (SV1)		Quota: None
Course Start	Full Year
Timetable	Timetable
Learning and Teaching activities (Further Info)	Total Hours: 200 ( Lecture Hours 44, Seminar/Tutorial Hours 44, Summative Assessment Hours 8, Revision Session Hours 1, Programme Level Learning and Teaching Hours 4, Directed Learning and Independent Learning Hours 99 )
Assessment (Further Info)	Written Exam 80 %, Coursework 20 %, Practical Exam 0 %
Additional Information (Assessment)	Coursework 20% Examination 80%
Feedback	Not entered
Exam Information
Exam Diet	Paper Name		Hours & Minutes
Main Exam Diet S2 (April/May)	Electromagnetism (PHYS09060)		3:00

Learning Outcomes
On completion of this course, the student will be able to: State the integral laws of electromagnetism and state and derive Maxwell's equations. Formulate and solve with vector calculus problems of static and time-varying electrical and magnetic field including utilisation of the electric scalar potential and the magnetic vector potential. Derive and apply the concepts of: Maxwell's displacement current; the continuity equation; self- and mutual inductance; Poynting's vector; energy flux; radiation pressure. 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. 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.

Reading List
None

Additional Information
Graduate Attributes and Skills	Not entered
Keywords	EMag

Contacts
Course organiser	Dr Jamie Cole Tel: (0131 6)50 5999 Email:	Course secretary	Mrs Siobhan Macinnes Tel: (0131 6)51 3448 Email:

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