Sort by
Refine Your Search
-
Listed
-
Country
-
Employer
- University of Oxford
- ;
- University of London
- Durham University
- KINGS COLLEGE LONDON
- AALTO UNIVERSITY
- DURHAM UNIVERSITY
- King's College London
- Nature Careers
- Royal College of Art
- UNIVERSITY OF VIENNA
- University of Cambridge
- University of Liverpool
- University of Nottingham
- ; CRUK Scotland Institute
- ; University of Exeter
- ; University of Southern Denmark
- Aston University
- Cardiff University
- Heriot Watt University
- Imperial College London
- MOHAMMED VI POLYTECHNIC UNIVERSITY
- University of Birmingham
- University of Hull
- 14 more »
- « less
-
Field
-
Postdoctoral Research Associate in Forest Resilience, Climate Change, and Human Health in the Amazon
holder will also co-supervise a PhD student who will be involved in the same project. This is a highly interdisciplinary project combining forest ecology, remote sensing, machine learning, epidemiology
-
to understanding the origins and progression of paediatric brain tumours and developing new therapeutic strategies. The lab combines genetic engineering, molecular biology, and translational research to investigate
-
• Uncertainty quantification around LLMs • Constrained optimal experimental design (active learning) • Combining models and combining data / Realistic simulation of clinical trials • Developing
-
. virology, immunology, microbiology, molecular biology, cell biology). Experience working with pathogens (ideally viruses) and/or host immunity is essential. The lab uses a combination of molecular techniques
-
cavity quantum optomechanics that combines strong light-matter coupling with strong exciton-phonon interactions in a single system. The tri-partite exciton-phonon-photon interactions within a single high-Q
-
full-time (35 hours per week), though we will consider part-time or flexible working patterns as well as requests for non-contractual hybrid working (combining a mix of remote and regular on-campus
-
) are interested in molecular organisation of cell interfaces in the epithelial tissue and glycobiology. We use super-resolution STED microscopy, CryoET, in combination with biophysics and chemical biology, to
-
. The project involves the combination of the use of cultured cells and vertebrate animals in particular zebrafish to understand newly-uncovered reactive metabolite signalling pathways of importance in well
-
. Research on this project will involve catalyst design, setting up small-scale hydrogenation reactions in batch and continuous flow, immobilisation of enzymes, combination of enzymes with metal nanoparticle
-
for the game changing impact of our science globally. Click here to find out more about working at the John Innes Centre. About the Howard Group: The Howard group combines mathematical and biophysical modelling