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and data-poor settings. Key research areas include stress prediction, reservoir deformation, fault reactivation, and the interaction between injected fluids, and rock properties. This project offers
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Experiences: Ph.D. in chemistry, materials sciences, polymer engineering, and/or related fields Experiences in biomass-derived materials Experiences in digital fabrication (3D printing, laser cutting, fluid
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in biofabrication, bioprinting and related fields. • Experiences in digital fabrication (3D printing, laser cutting, fluid dispensing) • Experiences in the design and manufacturing of scientific
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dynamics, turbulence, fluid dynamics, model interpretation, acoustic data, or field data processing. Additional desirable experience includes: bio-physical interactions, fieldwork, evidence of working at sea
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principles and recent observations on the nature of small, fluid-filled ‘cellular highways’ in the interstitial extracellular matrix (ECM) to identify, engineer, and leverage the role of confinement in cell
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breakwaters under varied sea conditions. 2. CFD and Finite Element Modeling Perform Computational Fluid Dynamics (CFD) simulations to optimize the design and performance of floating breakwaters. Develop finite
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, with a specific focus on complex biological systems. The project aims to apply highly controlled optical trapping techniques to investigate cell–fluid interactions during macropinocytosis (“cell drinking
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to optimize fluid flow, heat transfer, and current distribution within the electrolyzer. • Model key parameters such as overpotential, gas diffusion, ion transport, and pressure drop to improve overall
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, many-body physics, quantum information, quantum fluids, or cold atoms. Proficiency in numerical simulations is essential. The appointee will join CQT under the supervision of a group of researchers
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technologies and systems and the use of software such as Aspen Plus, TRNSYS, and Computational Fluid Dynamics will also be advantageous to the project. The appointee will also be expected to have excellent oral