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electron microscopy (4D-STEM) techniques. The Research Associate will design and execute in-situ experiments under liquid nitrogen and liquid helium conditions, including developing the hardware and
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flow visualisation and measurement techniques to study droplet impact under icing conditions to improve icing codes that aid in design and development of ice detection and mitigation system
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disproportionate loss of muscle mass compared to conventional ‘dieting’, which can have detrimental effects on physical function. The present fully funded PhD studentships will perform a series of human physiology
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-90% lithium-6 enrichment. The research group is using solvent extraction methods and crown ether extractants to carry out the lithium-6 enrichment process. This PhD will involve experimental lab work
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engines. The variable rotation speeds, complex loading and operating conditions cause significant blade vibrations. These vibrations, if not properly controlled and reduced, can lead to premature blade
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-hazards on physical/mental health, investigating associations between meteorological conditions (e.g., temperature), greenhouse gas (GHG) emissions, air quality, and health outcomes, and considering
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musculoskeletal conditions. Apos utilizes personally calibrated footwear with unique biomechanical elements attached to the sole of the shoe that alter the user's walking pattern, redistributing forces across
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operation of autonomous systems in complex, real-world conditions. This PhD project aims to develop resilient Position, Navigation and Timing (PNT) systems for autonomous transport, addressing a critical
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, combustion, and process optimisation. The project is focussed on the development of novel interface capturing Computational Fluid Dynamics methods for simulating boiling in Nuclear Thermal Hydraulics
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, embedded intelligence, and adaptive cyber-physical systems that operate safely under uncertainty and dynamic conditions. This PhD at Cranfield University explores the development of resilient, AI-enabled