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compressible gas dynamics, heat transfer, free-surface/melt behaviour, and mass transfer driven by phase change, within a GPU-accelerated solver to reduce simulation turnaround times. You will develop and
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compressible gas dynamics, heat transfer, free-surface/melt behaviour, and mass transfer driven by phase change, within a GPU-accelerated solver to reduce simulation turnaround times. You will develop and
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on large annotated datasets. Memory-efficient deep learning: Model compression, pruning, quantisation, selective memory replay, and efficient training strategies. Energy-efficient deep learning: Methods
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safety challenges. The foremost issue lies in storage, hydrogen’s low volumetric energy density requires it to be stored either as a compressed gas at extremely high pressures or as a cryogenic liquid at
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analysis and compression tests. The wound healing ability of the scaffolds will be investigated using a range of biological assays including live/dead assays to determine cytocompatibility, confocal
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early risk identification. This PhD project aims to design and develop personalised 3D-printed insoles with enhanced offloading performance and integrated sensing capability. The work will explore novel
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PhD Studentship: Nanopore Technology for Rapid and Accurate Measurement of Antibiotic Concentrations
for small-molecule sensing. By engineering nanopores with molecular recognition elements such as DNA aptamers, this project will enable multiplexed, real-time detection of diverse antibiotics, supporting both
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parcel delivery and environmental sensing. Equipped with diverse onboard sensors, including cameras and GPS, delivery UAVs hold significant potential for urban sensing applications such as infrastructure
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Almost all radar systems currently transmit from the same location. A drastic departure from this sensing architecture is distributed radar – enacted by a coherent network of spatially distributed
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and quorum sensing, offering new strategies to overcome resistance. Approach and Methods: Use cross-linking mass spectrometry to identify peptide targets in mycobacterial membranes Study effects on cell