Current research degree projects
Explore our current postgraduate research degree and PhD opportunities.
288 research degree projects
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Photonics and optoelectronics | Electronics and Computer Science | Engineering | Physics and astronomy
Quantum Reservoir Computing for photonic and quantum materials modelling
Quantum physics and artificial intelligence are converging to redefine how light–matter systems are explored and engineered. This project will develop Quantum Reservoir Computing as a new theoretical and computational framework, exploiting the dynamics of quantum systems to achieve efficient learning, prediction, and inverse design of photonic and quantum materials. -
Photonics and optoelectronics | Engineering | Physics and astronomy
Nonlinear photonics for quantum technologies
Nonlinear parametric photonics creates an interface between light and the atoms/ions and detectors used in quantum systems. This project combines novel fabrication approaches for nonlinear waveguides with established commercial materials to expand their operation into the ultra-violet and mid-infrared wavelength regions for use in practical quantum systems. -
Photonics and optoelectronics | Electronics and Computer Science | Physics and astronomy
Low-loss photonics for quantum networks
In the world of Quantum Technology every photon is precious. This project will create new ultra-low-loss optical components that will lead to advanced quantum memories, switchable delays, and the creation of large, entangled quantum states. -
Electronics and Computer Science | Chemistry and Chemical Engineering | Engineering | Physics and astronomy
Nanoscale quantum optoelectronic platforms for next-generation neuromorphic systems
This PhD explores quantum dots and perovskite nanocrystals to create nanoscale optoelectronic devices that mimic functionalities of the biological eye. You will design and integrate quantum-enhanced photonic systems for energy-efficient, high-speed neuromorphic computing and sensing, advancing sustainable and intelligent quantum technologies. -
Photonics and optoelectronics | Electronics and Computer Science | Engineering | Physics and astronomy
Wideband all-fibre polarisation-entangled photon pair sources for enhanced versatility in quantum optical experiments and quantum information processing
Quantum sources that produce entangled photon pairs are crucial components in many quantum applications. This project will develop fibre-based entangled photon sources based on poled silica fibre technology where entangled photon pairs are directly generated in an optical fibre thereby enabling the construction of low-cost, versatile sources for quantum applications. -
Electronics and Computer Science
Embodied quantum information flow for collective intelligence in robotic swarms
You'll explore how principles of quantum information flow and probabilistic entanglement can enhance coordination, adaptability, and resilience in multi-robot systems. The project bridges quantum technologies and embodied swarm intelligence, aiming to create a new class of collective robotic systems that think and act beyond classical limits. -
Electronics and Computer Science | Engineering | Physics and astronomy
MEMS/NEMS-integrated ultralow stand-by power quantum circuits
Novel Micro/Nano-Electro-Mechanical Systems (MEMS/NEMS) switches will be developed to significantly reduce overall power consumption of integrated quantum circuits. The MEMS/NEMS switches will be optimised for low temperature operation and will be integrated with existing quantum circuits to evaluate the energy efficiency of the systems. -
Mathematical sciences
Quantum computing and optimisation for large-scale energy system planning under uncertainty
This project explores how quantum computing can transform energy system planning for a net-zero Europe. By integrating quantum and classical optimisation methods, it will address uncertainty in renewable generation and develop scalable algorithms for large-scale stochastic models, advancing both optimisation theory and practical tools for the energy transition. -
Chemistry and Chemical Engineering | Mathematical sciences | Physics and astronomy
Quantum optimal control for symmetry-based NMR sequences
Symmetry is a powerful tool for selection of NMR interaction and creation of correlated spin states. Many exquisite experiments are based on analytical calculation via average Hamiltonian or Floquet theory. A step change in efficiency and robustness may be obtained by combining Hamiltonian symmetry, periodicity and quantum optimal control. -
Engineering
Reconfigurable origami phononic metamaterials for on-chip quantum acoustics
How about building programmable acoustic highways on a chip! Using origami-inspired phononic lattices, we will switch topological edge paths to route phonons between quantum devices with low loss and high isolation. The project includes multi-scale computational modelling and MEMS fabrication, leading to scalable quantum sensing, multiplexed readout, and adaptive routing.