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MPhys Physics with Astrophysics / Course details
Year of entry: 2021
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Course unit details:
Frontiers of Photon Science
|Unit level||Level 4|
|Teaching period(s)||Semester 1|
|Offered by||Department of Physics & Astronomy|
|Available as a free choice unit?||No|
Frontiers of Photon Science
1. To gain an appreciation of the techniques of photon science.
In particular, to understand how:
• ultrafast laser pulses are produced, characterised and used
• nonlinear frequency conversion techniques can be used to change the wavelength of laser beams
• terahertz-frequency light is produced and detected
2. To illustrate the application of these techniques in scientific research
3. To provide a suitable introduction to students wishing to pursue postgraduate research in
This course unit detail provides the framework for delivery in 20/21 and may be subject to change due to any additional Covid-19 impact. Please see Blackboard / course unit related emails for any further updates
On completion successful students will be able to:
1. Describe the equipment and techniques used by photon scientists to produce and measure ultrafast laser pulses in the UV, visible, infra-red and terahertz spectral regions.
2. Analyse the optical response of nonlinear materials and explain how it can be optimised to enable the significant wavelength conversion of laser beams.
3. Describe terahertz radiation and its effect on materials
4. Explain quantitatively how these techniques can be used in scientific research to gain an understanding of electronic processes occurring on a sub-nanosecond time-scale.
1. Producing ultrafast laser pulses (4 lectures)
Mode-locking; dependence of pulse length and peak power on mode number; active and passive techniques. Oscillator-amplifier systems.
2. Nonlinear frequency conversion (8 lectures)
Nonlinear optical materials; modification of the wave-equation; three-wave coupling; phase-matching; second harmonic and sum-frequency generation; optical parametric amplifiers and oscillators
3. Advanced ultrafast laser diagnostics (3 lectures)
Single- and multiple-shot autocorrelators. Frequency-Resolved Optical Gating (FROG). Spectral Phase Interferometry for Direct Electric-field Reconstruction (SPIDER).
4. Terahertz spectroscopy (4 lectures)
Pump-probe detection techniques. Methods of generating terahertz radiation (photoconductive antennas and optical rectification). Electro-optic sampling. Time-domain and frequency-domain techniques. Asynchronous optical sampling methods. Applications of terahertz spectroscopy (conductivity processes in semiconductors and biomolecules).
5. Ultrafast Transient Absorption Spectroscopy (5 lectures).
White light continuum generation. Application to carrier dynamics in quantum dots: state-filling effects; carrier cooling and recombination; carrier trapping; multiexciton effects including Auger recombination and biexciton binding energy. Mulitple exciton generation as means of exceeding the Shockley-Queisser limit to solar cell efficiency.
Feedback will be available on students’ solutions to problem sheets.
Dexheimer, S. L., Terahertz Spectroscopy, (CRC Press)
Hannaford P., Femtosecond Laser Spectroscopy, (Springer Science)
|Scheduled activity hours|
|Assessment written exam||1.5|
|Independent study hours|
|Darren Graham||Unit coordinator|
|David Binks||Unit coordinator|