317 algorithm-development-"Multiple"-"Prof"-"Prof"-"UCL" positions at University of Sheffield
Sort by
Refine Your Search
-
Listed
-
Category
-
Program
-
Field
-
vesicles in atherosclerosis. You will have an opportunity to further develop research expertise, cultivate grant writing skills, and contribute to scientific publications. The successful candidate will be
-
undergraduate and postgraduate programmes. Engage with the pedagogical development of the School and contribute to the School’s efforts to build a culture of educational leadership excellence. Conduct innovative
-
committee, leading the Careers and Development committee. Candidate A good undergraduate honours degree in a relevant science subject is required. Any further research stays, publications or experience with
-
. Specifically, the candidate will develop MR image acquisition methods and pulse sequences for both proton (1H) and hyperpolarised xenon (129Xe) pulmonary / cardiac MRI applications. These will include zero- and
-
downstream translational implications in developing better crops. Chloroplast is arguably the most important organelle for sustaining life as it is the main hub of photosynthesis, the process by which sunlight
-
retrofitted interventions such as SUDS (sustainable urban drainage systems). Working with project partners you will use the results to establish if and how urban developments can be reimagined, to improve
-
Overview We are seeking a motivated and hands-on Research Assistant to join an exciting interdisciplinary project at the University of Sheffield, focused on the development of a next-generation
-
-based sensing. This PhD project offers the opportunity to design and develop innovative optical measurement instrumentation based on one or more of these themes, evaluating their performance across
-
project offers an exciting opportunity to radically reimagine LPBF through the use of a novel hybrid multi-laser architecture. Working with exclusive, state-of-the-art laser systems developed at the
-
project offers an exciting opportunity to radically reimagine LPBF through the use of a novel hybrid multi-laser architecture. Working with exclusive, state-of-the-art laser systems developed at the