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calculations will be. The mathematical model will be defined based on the shape of the heat source and the heat flow density. At the same time, it is essential to consider the thermophysical and mechanical
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the PROMES laboratory (CNRS), a leading research center in concentrated solar energy and high-temperature systems. The research will take place at the Odeillo site, which hosts unique facilities for solar
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management Background: materials science, mechanical engineering, or a closely related discipline Apply: https://mgician.eu/research/doctoral-candidate-projects/dc6/ DC7: High-Performance Magnesium-Based
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, Zr, Hf, W, Ta, Mo, V, Cr, or Nb, all present in high concentrations. They combine a very high strength even above 1400°C and an excellent thermal stability, making them promising materials
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research opportunity focuses on advancing large-scale additive manufacturing using metal wire as feedstock and electric arc as the heat source. The project aims to develop an innovative and efficient method
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carbide (SiC) materials with high-temperature properties. The dissertation will focus on the preparation of silicon carbide ceramics using a novel approach without traditional sintering additives and at a
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, those materials experience a complex combination of fluid flow and interface phenomena, which dominate heat- and mass-transfer limitations. Traditionally, we reduce the complexity of the underlying models
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, Chemistry , Coherent Phenomena , Cold Atom Physics , Cold Atoms and Molecules , Cold QCD Group , collider physics , Collinear Fast Beam Laser Spectroscopy , Complex Quantum Systems , Computational Materials
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nanoagents aim at converting optical energy into heat to induce hyperthermia and a stress response in targeted biological tissues. From an external optical excitation, the energy is absorbed by the nanoagents
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of the complex physics governing the interaction between the heat source and the material. Additionally, it seeks to develop an efficient modelling approach to accurately predict and control the temperature field