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Field
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allowed computational fluid dynamics (CFD) to flourish, becoming an indispensable for many industries. Simulating the full Navier-Stokes equations is computationally prohibitive for most applications, so
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to electrochemisty and electromagnetics. Interface tracking/capturing methods such as immersed boundary method, level-set method, volume-of-fluid, phase filed method are options for model development.
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), renewable for 4 years. Informations Only applications submitted through the online platform are considered: https://careers.epfl.ch/job/Lausanne-PhD-positions-Experimental-unsteady-fluid-and-vortex-dynamics
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-liquid critical point. The dynamic nature of the degree of miscibility renders such fluid pairs to be applicable in several applications such as liquid-liquid mass transfer, flow pattern tuning to name a
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confined battery geometries. Advanced modelling—including computational fluid dynamics (CFD) and transient thermal analysis—is required to accurately capture heat flux distributions, temperature uniformity
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group, you will become part of a vibrant research environment specialising in nonlinear and quantum fluid dynamics. You will also have the opportunity to visit partner institutions and work with leading
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mechanics, and analytical and numerical methods to solve partial differential equations. Excellent oral and written communication skills. Prior experience in computational fluid dynamics or active matter will
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of Computational Fluid Dynamics CFD environment and simulations including: - Computation of the microwave field, Coupling of the microwave field with the plasma - Computation of elementary ionization, recombination
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advanced imaging, the project will map how ion transport and micro-fluid dynamics couple to interfacial energetics, explaining field-responsive changes that remain hidden in equilibrium-centric models
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the interaction between the structure of CFM and dynamic performance of the flow. The aim will be achieved through the following objectives: Develop a novel approach to investigate the fluid-solid coupling effect