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their optical properties. - Analyze species sampled in flames using laser-assisted mass spectrometry and optical spectroscopy; - Deduce the optimal operating parameters of the reactor to form species relevant
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of chemically storing and releasing hydrogen, using methanol as a reservoir. Main activities: • Utilize global optimization codes and perform DFT calculations on supercomputers. • Analyze results and
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partnership with the Charles Sadron Institute, - Contributing to the development of dedicated acquisition electronics, - Conducting tests on the developed devices, - Analyzing the obtained data, - Optimizing
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and optimization of metasurfaces exhibiting tailored spectral responses at selected near-infrared wavelengths • Development of angularly robust optical functionalities over wide ranges of incidence
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]. By combining simulations and experiments, comprehensive analysis of the process will be achieved and guidelines for optimization will be proposed. The analysis could then be extended to broader range
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after thermal treatment to maintain gas flow and optimal detection. The PhD student will learn the synthesis of nanomaterials and their integration with 3D printing techniques. The synthesized materials
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of neuronal and vascular responses; Contribute to the instrumental optimization of the imaging system (detector configuration, illumination control, multi-camera synchronization); Analyze and interpret
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, and optimization of various optical devices on chalcogenide materials for frequency conversion in the mid-infrared (2-20 µm) as well as for the detection of molecules by evanescent waves. 2) Improvement
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, nanostructuring, porosity) and their surface/interface physico-chemistry (functionalization, topography) in order to modulate or optimize their properties. The heterogeneous and complex structure of the studied
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described. From a technological perspective, optimizing radiative cavities is critical to improving the performance of TPV subsystems. Efficient cavity designs must maximize useful photon flux reaching