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interface. This PhD project aims to develop a flexible electrochemical sensing interface capable of capturing local physicochemical changes in real time. The work will explore biocompatible, deformable
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Researcher Profile First Stage Researcher (R1) Positions PhD Positions Country United Kingdom Application Deadline 16 Oct 2025 - 23:59 (Europe/London) Type of Contract Temporary Job Status Full-time Offer
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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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. Yet, many stellar and planetary parameters remain systematically uncertain due to limitations in stellar modelling and data interpretation. This PhD project will develop Bayesian Hierarchical Models
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avenues by enabling chronic, gut-based monitoring of neuroendocrine activity for applications such as closed loop therapeutics. The proposed PhD project sits at the interface of biomedical engineering
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Project Description: This EPSRC-funded PhD project will investigate how next-generation electric and autonomous vehicles can operate as symbiotic agents within the urban ecosystem—intelligently
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There is widespread concern about the negative impacts of plastic and other anthropogenic solid waste (hereafter referred to as ‘plastics’) on global biodiversity (Law, 2017; Lau et al., 2020). Such materials are extremely slow to break down, which has resulted in discarded micro- and...
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coherence bandwidth and thus bit rate are maximised. The PhD project will explore new techniques to overcome incoherent scattering in THz communications. The overall research aim is to lay down a measurement
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Northwest Eurasia owes its anomalously temperate climate to the oceanic circulation cell known as the Atlantic Meridional Overturning Circulation (AMOC). Regional warmth is maintained by northward-flowing Atlantic surface currents – including the Gulf Stream – that lose their heat...
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. This PhD project will explore a novel approach: leveraging polymeric microelectromechanical systems (MEMS) technology to create a miniaturised micropump-based ingestible capsule that can actively deliver