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Posted by Kate Stuart on Wednesday, March 18, 2026 in Job Opportunities . The Cruchaga lab (https://cruchagalab.wustl.edu/ ) at Washington University School of Medicine has a
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methods § Skilled in modeling electro-optical nano-systems to predict properties and fluid dynamics. § Highly skilled in multiple scripting languages, including MATLAB, Python, Optiwave (FDTD), COMSOL
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paradigms (such as self-attention mechanisms) in the context of reduced-order models, as well as their application to areas of interest in engineering like, e.g., computational fluid dynamics, are key
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, and glucose and insulin tolerance tests. This is a highly collaborative project where the candidate will have to interact with the Animal Care & Use Program, IACUC, ULAM, the Mouse Metabolic Phenotyping
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with open source software frameworks and/or using modern open source code development methodology is highly desirable, as is experience with numerical methods pertaining to fluid dynamics or plasma
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to investigate the flow dynamics induced by periodic roughness while drastically reducing the computational cost compared to full DNS or global stability analyses. These approaches will make it possible to explore
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Combustion, vol. 84, p. 25–47, April 2009 web . [9] P. J. Schmid, «Dynamic mode decomposition of numerical and experimental data,» Journal of Fluid Mechanics, vol. 656, p. 5–28, July 2010 web . [10] S
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, and 3D such as Tomo-PIV and STB), hot-wire anemometry, high-speed imaging, Planar Laser Induced Fluorescence, dynamic pressure measurements. Experience writing journal papers in leading fluids journals
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for simulation and modeling of wave dynamics, and for uncertainty quantification of extreme events. The project will combine stochastic mathematical models of wave physics with advanced computational methods
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, aqueous fluid dynamics, physiology, and biomedical engineering. Methodologies in the lab: cell culture (primary human and immortalized cells from the conventional outflow pathway) molecular biology