Sort by
Refine Your Search
-
Listed
-
Category
-
Employer
- Cranfield University
- ;
- University of Nottingham
- ; Swansea University
- ; The University of Manchester
- University of Sheffield
- ; University of Nottingham
- ; University of Southampton
- ; University of Bristol
- ; University of Birmingham
- ; University of Surrey
- AALTO UNIVERSITY
- University of Cambridge
- ; Brunel University London
- ; Newcastle University
- Newcastle University
- ; Cranfield University
- ; Loughborough University
- ; University of Cambridge
- ; University of Plymouth
- ; Aston University
- ; EPSRC Centre for Doctoral Training in Green Industrial Futures
- ; Imperial College London
- ; King's College London
- ; The University of Edinburgh
- ; University of Exeter
- ; University of Hertfordshire
- ; University of Oxford
- ; University of Reading
- ; University of Sheffield
- ; University of Strathclyde
- ; University of Sussex
- Aston University
- Harper Adams University
- Heriot Watt University
- Imperial College London
- University of Liverpool
- University of Manchester
- 28 more »
- « less
-
Field
-
mechanical and chemical properties; fully 3D-printed electronics; and devices with mechanical or electrical responses encoded into their structure. However, we don’t yet know how to design these complex
-
critical to ensuring the longevity and safety of fusion reactors. This PhD project focuses on developing an integrated framework that combines cutting-edge computational models, including Monte Carlo
-
to deepen our understanding of IAI mechanisms and develop innovative antibacterial biomaterials to improve patient outcomes. Structured around three core scientific pillars-regenerative medicine, biomaterial
-
Funding providers: The FSE Doctoral Focal Award, Swansea University and Leaf Tech Ltd The subject areas: Materials Science, Chemistry, Chemical Engineering, Electronics, Mechanics, Polymers, other
-
spaces and habits for them. This is a highly interdisciplinary project that combines computational modelling and behavioural science. The first part will be based on the use of state-of-the-art
-
subsample of children with craniopharyngioma and healthy controls. Part 3 will involve an intervention neuroimaging study (EEG and/or fMRI) in healthy controls, aiming to illuminate the mechanisms through
-
resistance and a profoundly immunosuppressive tumour microenvironment (TME). There is a critical need for novel therapeutic strategies that target both tumour-intrinsic mechanisms and immune evasion. Our
-
this advanced manufacturing process will open new opportunities: devices with variable mechanical and chemical properties; fully 3D-printed electronics; and devices with mechanical or electrical responses encoded
-
: This position is ideal for candidates with a background in civil engineering, structural engineering and mechanical engineering. Applicants should demonstrate: A strong interest in both experimental and numerical
-
£20,780 per year, and includes a 3-month fusion engineering CDT training programme as part of the 2025 Cohort. This project is co-supervised by Dr Chris Hardie from UKAEA. The UoB Materials for eXtremes