Current research degree projects
Explore our current postgraduate research degree and PhD opportunities.
Explore our current postgraduate research degree and PhD opportunities.
Working with the National Nuclear Laboratory (NNL), this project will develop new in-situ systems for contaminant and risk management at nuclear (and other) sites, based on novel electrokinetic approaches developed at the University of Southampton.
Why do cells need peroxisomes? In this project we will use a combination of molecular and cell biological techniques to understand the role that peroxisomes play in neuronal development and stress response. We will establish tools to investigate peroxisome formation and function based on the peroxisomal probes developed in the lab.
Alzheimer’s disease (AD) is a neurodegenerative disease, with a complex biology. We aim to explore the cellular and molecular mechanisms underlying tau pathology in the absence or presence of systemic inflammation. The results may lead to improved understanding of the biological mechanism underlying spreading of Tau in the AD-affected brain.
Southampton Business School has an ambitious quality-driven strategy of growth and our research is recognised throughout the global academic community.
Southampton Business School has an ambitious quality-driven strategy of growth and our research is recognised throughout the global academic community.
Southampton Business School has an ambitious quality-driven strategy of growth and our research is recognised throughout the global academic community.
Southampton Business School has an ambitious quality-driven strategy of growth and our research is recognised throughout the global academic community.
Southampton Business School has an ambitious quality-driven strategy of growth and our research is recognised throughout the global academic community.
Southampton Business School has an ambitious quality-driven strategy of growth and our research is recognised throughout the global academic community.
This project aims to combine passive acoustic noise interferometry and distributed acoustic sensing of seafloor cables embedded with machine learning. This novel, coherent combination will sustainably enable at low-cost, spatially resolved high-resolution real-time insights into physical attributes such as temperature, water-velocity or pressure of the water column and the cryosphere.