Prospective students
If you're interested in studying this course, you can find more information on our prospectus:
Student handbook
Course overview
Photonics is of key importance in many areas of research in natural science engineering and medicine. Preparing students for academic research in these areas benefits greatly form a formal training in fundamental aspects of optics, and the development of an extended project at the forefront of current research activity. Building on foundations taken from the MSc in Optics and Photonics, the MRes in Photonics is intended to provide this training. Imperial has offered an advanced programme in optics for over 90 years and the MRes Photonics draws on our experience as one of the largest centres for optics-based research and application in the UK.
This programme forms the first year of a 1+3 structure for students who have been offered a place to take up a PhD on completion of the programme, if they do not already have the significant grounding in Photonics necessary for their PhD project.
The main coursework (lectures and laboratory work), which takes place in the first term, consists of practical laboratory work and three lecture-based modules that together provide a key grounding in some of the essential knowledge and skills underpinning photonics. You choose further lectures from the elective modules available (either in Term 1 or Term 2). The laboratory work provides key training in basic skills and techniques widely used in photonics research. The main module of your studies is a nine-month, full-time MRes research project starting in January which is usually carried out in an academic research group, working at the forefront of their current research.
Course Director
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Professor Chris Dunsby
Personal details
Professor Chris Dunsby Professor of Biomedical OpticsLocation
622
Blackett Laboratory
South Kensington Campus -
Professor Mark Neil
Personal details
Professor Mark Neil Professor of PhotonicsLocation
608
Blackett Laboratory
South Kensington Campus
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Dr Mary Matthews
Personal details
Dr Mary Matthews Lecturer in Ultrafast ScienceLocation
6m73
Blackett Laboratory
South Kensington Campus
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Dr James McGinty
Personal details
Dr James McGinty Senior LecturerLocation
621
Blackett Laboratory
South Kensington Campus
Course Structure
Module | Term | ECTS | ||
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PHYS70024 | Imaging | Compulsory | Autumn | 5 |
The Imaging module is split into two parts: geometrical optics and wave optics. Geometrical optics introduces you to the ray model for light propagation through optical systems and methods to model aberrations. The wave optics part introduces methods to model the propagation of scalar waves through optical systems and how this can be used to describe image formation for both coherent and incoherent illumination. |
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PHYS70025 | Lasers |
Compulsory |
Autumn |
5 |
Lasers underpin much of commercial and research optics and photonics. This module provides a basic introduction to the physics of lasers including 3 and 4-level lasers, the conditions required for gain and laser operation, control of the spectral properties of laser emission, Q-switching, modelocking and the different types of laser gain media, spatial laser modes, Gaussian beam propagation and includes an introduction to the topic of nonlinear optics. |
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PHYS70026 | Optical Measurement and Devices |
Compulsory |
Autumn |
5 |
Optical measurement techniques are important to manufacturers and users of optical equipment and in a wide range of applications. Polarisation, interference and coherence are aspects of light that can be exploited for a broad range of measurement techniques and form the foundation of many optical devices. This module introduces these phenomena and provides frameworks for describing, understanding and exploiting them. The module gives details of the underlying generic optical concepts, their mathematical representation and their practical applications. |
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PHYS70049 | Photonics Laboratory |
Core |
Autumn |
7.5 |
You will follow a set of experiments ranging from short introductory experiments, through to longer experiments. You will be exposed to a wide variety of optical techniques and phenomena that you will also see in taught lecture modules. |
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PHYS70050 | MRes Research Project |
Core |
Spring-Summer |
60 |
A nine-month research project is the largest core module of the MRes Photonics. You will work on a state-of-the-art problem within a research area of photonics, all embedded within a research group and under the guidance of research-active staff. You will agree a project through discussion with project supervisors at the start of the academic year. |
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PHYS70007 | Optical Communications Physics |
Elective |
Autumn |
5 |
This module builds on the Oscillations and Waves, E&M and Solid State Physics core modules, and develops understanding of how modern optical communications technologies operate. The module considers optical fibres and the surrounding optoelectronic and photonic technology, classical information theory and data encoding, and network infrastructure. Module spec can be found here. |
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PHYS70029 | Optical Design |
Elective |
Spring |
5 |
The module introduces Seidel aberration theory to describe and enumerate the aberrations that arise in optical imaging systems such as compound lenses and mirrors. It studies arrangements of optical surfaces that are able to control or minimise aberrations and investigates both theoretical and practical design processes using an industry standard computer aided design package. |
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PHYS70017 | Laser Technology |
Elective |
Spring |
7.5 |
An introduction to principles and practice of laser devices and nonlinear optical technology. The module will provide an understanding of the key physical concepts underlying laser and nonlinear optics and their contemporary applications. Students will be equipped with sufficient knowledge to be able to use and understand lasers and nonlinear processes in the subsequent research or commercial careers. Module spec can be found here. |
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PHYS70031 | Biomedical Imaging |
Elective |
Spring |
5 |
An introduction to principles and practice of biomedical imaging technologies, including microscopes, fluorescence and tomography. The module will provide an understanding of the challenges presented by tissue samples, in vivo and ex vivo systems. You will be equipped with sufficient knowledge to be able to use and understand a biomedical imaging system in subsequent research or industry settings and will gain knowledge of latest research frontiers. |
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PHYS70032 | Opto-electronic Devices |
Elective |
Spring |
5 |
An introduction to the most important device components from the worlds of optical telecommunication, space lighting, optical displays and sustainable energy production. You will acquire advanced mastery of the principles of diode laser action and design, and you will explore how quantum theory can be harnessed to improve performance in nano-scale devices. You will also consider the key factors affecting the use of photovoltaics and LED lighting as part of a sustainable energy future. You will examine the operation of optical displays, how the human visual system works and the way in which it perceives light and colour, and the operating principles behind many displays and their development. |
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PHYS70033 | Fibre and Ultrafast Lasers |
Elective |
Spring |
5 |
This module is an introduction to fibre lasers and ultrafast lasers. It will cover the fundamentals of optical fibres and how they can be used as laser gain media, the generation and characterisation of ultrafast optical pulses and relevant examples of ultrafast pulsed lasers. You will gain an understanding of how fibre and ultrafast lasers work and gain insight into why they are such useful tools in a wide variety of scientific and industrial applications. PHYS70033 O&P Fibre & Ultrafast Lasers |
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Credit Total | 90-92.5 |
We expect most students will finish with 90ECTS. However, it is possible to finish with 92.5 ECTS if a combination of higher weighted electives is chosen. This involves a greater workload and should be discussed with your Mentor or the Programme Director before committing to this option.