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materials-based heterostructures , where the 2D nanosheets will act as transducers for electrical sensing applications. This will generate a knowledge-based platform to allow us to rationally engineer 2D
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materials-based heterostructures , where the 2D nanosheets will act as transducers for electrical sensing applications. This will generate a knowledge-based platform to allow us to rationally engineer 2D
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materials-based heterostructures, where the 2D nanosheets will act as transducers for electrical sensing applications. This will generate a knowledge-based platform to allow us to rationally engineer 2D
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, collaborative environment at our Newcastle city‑centre campus. About you To succeed, you will bring: PhD (or thesis submitted) in Mechanical/Materials/Electrical Engineering, Physics or related field
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of controllable long-range dipole-dipole interactions, long trap lifetimes and strong coupling to electric and microwave fields. The postholders will be expected to display the initiative and creativity, together
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forefront of hydrogen technologies and their integration to the energy systems. The successful candidate will hold a PhD degree (or close to completion) in Mechanical/Electrical Engineering or related subject
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into ‘Mechanisms and treatment of nausea’. This will focus predominantly on functional studies with human gastrointestinal tissues, investigating the effects of therapeutic electrical stimulation
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internal structure, combined with the existence of controllable long-range dipole-dipole interactions, long trap lifetimes and strong coupling to electric and microwave fields. The postholders will be
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close to completion) in Mechanical/Electrical Engineering or related subject, with a proven track record of publishing in high quality international academic journals and experience of working as a
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treatments. To achieve this, we will develop personalised cardiac models at scale, and update these models over time, using imaging and electrical data collected by collaborators at multiple centres. We