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Supervisory Team: Prof Johan Nilsson, Dr William Kerridge-Johns Project description: This project, focussing on high-power laser architectures, will contribute to a major Ministry of Defence (MoD
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materials processing and other important laser applications. Fundamentally, their advantages derive from rapid and flexible control of the beam shape and polarisation. Adding to this, computer control
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or ultracold cryogenic systems. This practical project will enable you to develop experimental skills in laser spectroscopy, quantum and non-linear optics, cryogenics, RF electronics, data analysis, control
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commercial skills. Optical fibres can transport light over long distances with very low loss. However, transporting quantum bits (qubits) using photons suffers from the interaction of the qubits with the glass
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angstrom. To accomplish this, coherent x-rays from a synchrotron light source are used to illuminate a single nanocrystal which scatters to produce a diffraction (speckle) pattern. That pattern encodes all
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entirely composed of surface atoms. Examples of the properties include light-plasmon non-linearities and in particular the possibility of grating coupling to surface plasmon polaritons using a photoinduced
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to investigate novel concepts for high power lasers operating in the visible and ultraviolet (UV) wavelength bands. Scaling laser power in the visible and ultraviolet bands remains as one of the most significant
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) p.a. is available to investigate power scaling approaches for fibre lasers operating in the two-micron wavelength band. Two-micron fibre laser technology has the potential to yield a wealth of new
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fields of science and engineering like light weight design, engineering, medical applications, dampers, energy absorbers, thermal management, artificial intelligence and many more. The proposed topic
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, commonly referred to as meta-atoms, arranged in either a periodic or aperiodic fashion, have garnered growing interest for their extraordinary ability to control light in both classical and quantum domains