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Field
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to understand the fluid dynamic fragmentation and vaporization of laser-impacted thin liquid tin targets: what really happens when a laser pulse hits a tin droplet? New fluid dynamics understanding will lead to
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flow metrics as a function of the above factors. It uses a Fluid Structure Interaction (FSI) approach, with a Computational Fluid Dynamics blood flow model coupled to a structural Finite Element model
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Research theme: water wave mechanics, physical oceanography, computational fluid dynamics How to apply:uom.link/pgr-apply-2425 Number of positions: 1 This 3.5 year PhD is directly funded through
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background in thermal modeling, heat transfer, and fluid dynamics. Knowledge of numerical simulation tools (COMSOL, ANSYS, or similar). Hands-on experience with experimental thermal characterization. Ability
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investigation, and computational fluid dynamics (CFD) modelling. Experience in biomedical research is highly regarded. How to apply Apply for this scholarship at the same time you apply for admission to a QUT
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. Experience with numerical modelling techniques (e.g., DEM, FEM), computational fluid dynamics (CFD), and/or experimental methods (e.g., X-ray radiography, TDR) is highly desirable. Successful candidates will
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engineering; Experience in computational fluid dynamics is appreciated Assertive student with a strong academic standing. We welcome applicants with diverse backgrounds to enrich our dynamic and diverse
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overcomes the geographic limitations of conventional systems, enabling global scalability and accessibility. Using advanced computational fluid dynamics (CFD) approaches, the project is aimed at deepening
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at foreign educational institutions Be prepared for changes to your work duties after employment. Required selection criteria You must have an academically relevant background within fluid dynamics and/or
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technological solutions for the recycling of waste heat in specific food industry settings, using computational fluid dynamics modelling, lab experiments and field work To disseminate finding in high impact