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or cooling. These qualities are obtained through exchanges between water vapor and “bound water”, i.e., water absorbed in the solid structure, combined with heat transfers. Consequently, understanding and
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are developing the concept of particle-based solar power plants. In this concept, particles are used as a heat transfer fluid and thermal energy storage material. The particles are heated in a receiver exposed to
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of diffusion of the antisolvent in the liquid solution, fragmentation of the jet, evaporation of the liquid, turbulent mixing, dissipation and transfer of heat in the mixed layer between the two fluids
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on a simplified model (1D) considering heat and mass transfer correlations, will be investigated how a "pillow plate" geometry can meet the process specifications. A 3D reactor geometry incorporating
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carried out, the aim of this project is to take a further step forward in our understanding of heat transfer phenomena involving impinging pulsed micro-jets. This will be achieved through an experimental
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processes of matter transfer, heat and flows, physical chemistry such as kinetics and thermodynamics, physical chemistry and biology, taking into account the complex interactions and interdependencies between
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of these two types of porosity. These porosities will contribute to modifying the distribution of mechanical stresses and heat transfer within the material. It is therefore essential to characterize the density
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/hyperthermia based on a deep understanding of a heat transfer at nanoscale and a precise temperature readout permitting to optimized and controlled “hot spots” effect triggered by magnetic field or light
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the area of experimental and modeling of combustion and heat transfer. The successful candidate will study oxy-combustion in a high-pressure combustor. This work combines experiments and modeling
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, 34 S, and 36 S, with 32 S being the most common with 95% abundance. Typically, chemical reactions at high temperature do not differentiate between isotopes. However, fractionation of sulfur isotopes is