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of spindles, the positioning and transport of cellular organelles, and fluid-structure problems in biology. To address these, often in close collaboration with experimental collaborators, we build numerical and
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technologies with real-world impact. Key Responsibilities: Design and develop electrochemical sensing interfaces tailored for fluid-free detection of solid-state analytes, including skin-emitted metabolites
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giants and icy moons. This will be achieved through a multi-method approach, combining rotating fluid mechanics experiments, numerical simulations, and theoretical analysis. As a key member of the team
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eHC and atmospheric conditions. You will also need to experimentally characterise the heat release rate (HRR), flammable and toxic gases emissions of various types of batteries potentially deployed in
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experimental collaborators, we build numerical and theoretical models from the ground up, revealing how the known mechanics of individual components give rise to collective behavior. Many such phenomena occur
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heat and mass transfer, thermal comfort, and computational fluid dynamics (CFD). These skills will be applied to design, evaluate, and optimise strategies that enable the effective implementation of MMV
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optical and mechanical simulations, possibly also computational fluid dynamics. Fabrication of the PIC in cleanroom facilities in Norway (NTNU Nanolab and at UiT), including process optimization and
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that will define the CNRE. CNRE research is both computational and experimental; we work on exciting problems in diverse areas such as bio-fluid interactions, signatures, wave energy, advanced materials
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optical and mechanical simulations, possibly also computational fluid dynamics. Fabrication of the PIC in cleanroom facilities in Norway (NTNU Nanolab and at UiT), including process optimization and
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properly. Please turn on JavaScript in your browser and try again. UiO/Anders Lien 15th August 2025 Languages English English English PhD Research Fellow in fluid mechanics of droplet flow on complex fibers