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Field
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exchange energy at such rapid rate that they blend together to form hybrid states at room temperature (strong coupling regime). We recently shown that one can control the quantum state and interaction
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easier to detect and measured experimentally. However, it is not well known yet how this process emerges and how one can control it. This PhD project will focus on developing the necessary theoretical
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explore ways to control their motion in 3D space. Synthetic microswimmers have many potential biomedical applications, including targeted drug delivery and non-invasive medical treatments. The swimmers
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(PBs) offer a promising alternative, reducing wave energy through dissipation and controlled overtopping, potentially mitigating flood risk while minimising environmental impact (Nimma & Srineash 2025
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be undertaken at Imperial College London (Control and Power Research Group, Department of Electrical and Electronic Engineering) under the co-supervision of Professor Balarko Chaudhuri and Professor
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. Entry requirements: Applicants will normally need to hold, or expect to gain, at least a 2:1 degree (or equivalent) in Mechanical Engineering, Electrical Engineering, Mechatronics and Control Engineering
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Supervisors Primary Supervisor - Dr Calum Williams Secondary Supervisors - Dr. Maciej Dabrowski , Prof Simon Horsley This PhD studentship will develop 3D-printed optical metamaterials to control
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of how a changing climate shapes planet Earth. Our hypotheses, which you will refine and test are: 1. Bedrock channel incision in Tenerife is locally controlled by the climatic regime. 2. River profiles
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improve surgical workflow, shortens surgery time, enables unrestricted movement tracking, and reduces infection risks. Eliminating markers enables robot-assisted or fully automated femoral implantation
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understanding of plasmid regulation and its role in controlling plasmid spread and pollutant bioremediation in complex microbial communities. Plasmid regulatory genes are widespread among divergent plasmids in a