Current research degree projects
Explore our current postgraduate research degree and PhD opportunities.
Explore our current postgraduate research degree and PhD opportunities.
The University of Southampton is expanding its PhD research in the area of Quantum Technology Engineering. In addition to the research project outlined below you will receive substantial training in scientific, technical, and commercial skills.
The University of Southampton is expanding its PhD research in the area of Quantum Technology Engineering. In addition to the research project outlined below you will receive substantial training in scientific, technical, and commercial skills.
The University of Southampton is expanding its PhD research in the area of Quantum Technology Engineering. In addition to the research project outlined below you will receive substantial training in scientific, technical, and commercial skills.Membrane quantum well lasers contact-bonded onto the surface of sapphire or silicon carbide have been demonstrated to create perfect Gaussian beams. We have the capability to release these membranes and position them in the integrated photonics cleanroom on top of substrates and we have demonstrated external cavity lasing with them.
The University of Southampton is expanding its PhD research in the area of Quantum Technology Engineering. In addition to the research project outlined below you will receive substantial training in scientific, technical, and commercial skills.Colloidal quantum dots are semiconductor nanocrystals that sit in between molecular and bulk materials. Their small size (typically <10 nm in diameter) are comparable to the material’s Bohr radius, leading to quantum confinement of excitons and size- and composition-tunable optoelectronic properties. Compared to other quantum-confined nanostructures (e.g. epitaxial quantum dots, wires or wells) they have the advantage of being solution-processable, which makes them well suited for mass production of devices.
The University of Southampton is expanding its PhD research in the area of Quantum Technology Engineering. In addition to the research project outlined below you will receive substantial training in scientific, technical, and commercial skills.
The University of Southampton is expanding its PhD research in the area of Quantum Technology Engineering. In addition to the research project outlined below you will receive substantial training in scientific, technical, and commercial skills.Membrane quantum well waveguide lasers are a more flexible route to hybrid silicon/III V laser structures in which a III V quantum well membrane laser is contact-bonded onto the surface of silica on silicon substrates (see Optics Express 30, 32174 (2022)). We have the capability to release these membranes and position them in the integrated photonics cleanroom. The membrane quantum well lasers can provide lasing in-plane as a single laser or an array of coherent lasers without the use of an external cavity. They show the potential to be integrated with silicon photonics as the light source. Here we want to combine these laser sources with meta-surfaces. Meta-surfaces, harnessing subwavelength 2D nanostructures, 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 light (see Nature Photonics 15, 327 (2021)).
Around 70% of Europe’s offshore wind turbines are installed in the North Sea. Chalk, a calcareous weak rock, is widely present in this area. Driven piles are currently the preferred foundation system for these structures, but pile design entails a high level of uncertainty. Our recent collaborative work on helical (‘screw’) piles has indicated their potential suitability for these highly challenging offshore applications. The relative ease of installation of screw piles at depth may offer a much more convenient method for anchoring wind turbine foundation systems. This can potentially reduce the cost of offshore renewables, accelerate the rate of infrastructure deployment, and significantly contribute towards meeting energy decarbonisation targets.
Metaoptics, the application of metasurface concepts in optical systems, is a rapidly growing field that has the potential to revolutionise a wide range of applications, such as sensing, imaging, and telecommunications. The design and fabrication of high precision, large-area metaoptic components requires achieving high precision and accuracy over a large diameter. Next to making metamaterial devices that are very good at one particular function, there is a strong interest to develop multifunctional metasurfaces with properties that can be controlled or programmed after the initial fabrication. By combining metaoptics with novel materials that can change their state depending on electrical or optical control signals, new types of applications can be enabled.
Applications are invited for a fully funded PhD position on the investigation of novel design methods to improve the resilience of submerged infrastructure (i.e. bridge piers, wind turbines) subject to hydrodynamic action (e.g. currents and waves).Many critical submerged infrastructures are exposed to increased risk due to climate-induced changes in environment conditions, such as increased river current or wave action. In order to design the next generation of submerged infrastructure that are sustainable and both cost and carbon efficient, new design methods are required.
We are seekign an outstanding chemistry student with an interest in chemical biology to work on a project to develop cyclic peptide inhibitors of a protein-protein interaction that is heavily implicated in the development and growth of tumours.Mutant RAS proteins drive numerous cancers, with their inhibtion shown to have therapeutic potential in several tumour types. The majority of RAS inhibitors currently in development target the G12C KRAS mutant through a covalent inhibition mechanism, which limits their use to a small subset of cancers. The Tavassoli lab has used an in-house genetically-encoded library of cyclic peptides to identify several cyclic peptides that inhibit the interaction of RAS proteins with their affectors, and therefore inhibit downstream signalling in cancer cells.