- Professor Nicholas Mitchell (Professor, Department of Electronic & Electrical Engineering, The University of Bath - The University of Bath)
|Delivery Type||Delivery length / details|
|Lecture||22 x 1 Hour Lectures|
|Assessment Type||Assessment length / details||Proportion|
|Semester Exam||2 Hours Written Exam||70%|
|Semester Assessment||Coursework Deadlines (by week of Semester): Assignment (15%) in Week 8 (approx) Assignment (15%) in Week 11 (approx)||30%|
|Supplementary Exam||2 Hours Written Exam||100%|
On successful completion of this module students should be able to:
1. Describe what is meant by laser light, in the context of the functionality of different types of laser systems, and appreciate the importance of lasers as scientific and technological tools.
2. Classify the major causes of attenuation and dispersion of light in optical fibres and analyse the means by which these can be minimised.
3. Analyse the design of optical modulators/devices, based on the electro-optic and acousto-optic effect, and the non-linear interactions of intense laser light.
4. Describe and evaluate the mechanisms of iridescence and structural colour in photonic crystals, in terms of dielectric periodicity in optical structures and the formation of optical band-gaps.
5. Derive the basic principles of optical hologram formation, and thus describe the key elements of practical holography.
6. Present a qualitative appreciation of the concepts of “Quantum Optics”; where photons of light are treated as quantum mechanical entities.
This module will cover a number of topics in Modern Optics, with a particular theme of how photons can replace electrons as the principal information-processing agents. The module will discuss optical sources (including lasers in detail), optical fibres and waveguides, non-linear optical effects, optical modulation and signal processing, photonic structures, holography and optical storage.
Absorption, spontaneous emission of radiation and the Einstein relations.
Laser radiation theory leading to the necessity for population inversion.
Population inversion and three- and four-level systems.
Threshold condition for laser cavities and mode structure of laser light.
Examples of practical laser systems including solid state lasers, gas lasers, excimer lasers, dye lasers and semiconductor lasers.
Continuous wave and pulsed lasers; theory of mode-locking, ultra-fast lasers.
Snell's law, dispersion and attenuation in optical fibres.
Single mode and graded index fibres.
Materials for optical fibres, fibre manufacturing.
Polarisation effects in media, harmonic frequency generation.
Parametric generation of light, white-light continua.
Other nonlinear processes; e.g. Kerr effect, multi-photon absorption.
MODULATION OF LIGHT
Birefringence and electro-optic modulators.
The acousto-optic effect.
The basics; periodicity in optical structures.
Optical band-gaps, group velocity dispersion and optical density of states.
Modeling of photonic crystals, plane-wave and FDTD simulations.
Practical realisations of photonic crystals, iridescence and structural colour, integrated optics.
Introduction to Plasmonics.
Practical examples; the Gabor hologram, volume holograms.
Holographic lithography & optical data storage.
This module is at CQFW Level 6