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collaboration between the Process Intensification Group (PIG) and Materials, Concepts, and Reactors group (MatCoRe), so the successful candidate will be well supported. Additive manufacturing/3D printing and Net
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fermentation–separation processes to enhance efficiency and reduce fuel costs and lifecycle greenhouse gas (GHG) emissions. Research Activities Strain screening: Identify and evaluate microbes for efficient C5
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work employing group 1 metals to enable sustainable, mechanochemical processes (see: Nature Synthesis, 2025, ASAP and J. Am. Chem. Soc. 2025, 147, 40895 ). The aim of the project is to develop a series
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they replicate the responses seen in people. 3D bioprinting techniques are an exciting set of fabrication technologies which build on the principles of 3D printing, but which can process cells and other biological
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discussion. For questions about the application process, please contact gps.pgr@newcastle.ac.uk
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programmed in advance. If anything changes, it may fail. This project explores how to build more adaptable systems using vision-language-action (VLA ) models. These combine computer vision (to see), natural
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explore key physical processes governing CO2 plume migration, trapping mechanisms, and fluid–rock interaction under realistic subsurface conditions. The goal is to generate insights that improve the safety
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have the opportunity to develop their computational modelling capabilities in this project, alongside learning new skills such as testing on biological tissues and medical image processing
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-weather perception for which Radar sensing/imaging is essential. This project focuses on developing algorithms, using signal processing/machine learning techniques, to realise all-weather perception in
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yield and productivity. Robust yeast and bacterial strains will be studied alongside continuous, integrated fermentation–separation processes to enhance efficiency and reduce fuel costs and lifecycle