672 structural-engineering "https:" "https:" "https:" "https:" "https:" "U.S" positions at University of Sheffield
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flow, carbon/conduction networks and additive structure of powders to be used in dry electrodes. The development, investigation and optimization of dry, solvent-free manufacturing processes
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-vesicular structures. They are key information transporters between cells, responsible for the proliferation of multiple diseases including cancers. EVs have been demonstrated to contribute to cancer invasion
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of fungal cell wall damage to identify new therapeutic targets and determine the structural changes to the fungal cell wall in response to fungicidal and fungistatic treatments, host and environmental
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vancomycin resistance in Clostridioides difficile that incur high fitness costs in key pathogenicity traits. PLoS Biology (2024) 22: e3002741. https://doi.org/10.1371/journal.pbio.3002741 4. Structural
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Advancing Blood Pressure Monitoring with Wearable Technology and Multimodal AI (S3.5-COM-Sun) School of Computer Science PhD Research Project Competition Funded Students Worldwide Dr Shaoxiong Sun
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with core data analysis and professional skills that are necessary for bioscience research and related non-academic careers. https://www.yorkshirebiosciencedtp.ac.uk Project Description: The oestrogen
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. Funding Notes This project is for Self-funded students or students with external funding. References https://gravity-cosmology.sites.sheffield.ac.uk/phd-projects https://sites.google.com/a/sheffield.ac.uk
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://www.recyclamine.com/ https://www.abg-am.com/portfolio/chemistry/recyclamine-technology/F008?tab=1 https://www.siemensgamesa.com/global/en/home/explore/journal/recyclable-blade.html https://interregtiger.com/paimpol
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Intelligent active gate driver for net zero energy systems (S3.5-ELE-Foster) School of Electrical and Electronic Engineering PhD Research Project Competition Funded Students Worldwide Prof Martin
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label proteins and DNA substrates, then use advanced instrumentation to record their dynamic behaviour in real time. smFRET will reveal nanometre-scale structural changes as polymerases work, while