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evaluation of modal-decomposition techniques applied to data from high-fidelity numerical simulations of landing-gear aeroacoustics. The researcher will develop and implement modal-decomposition methods using
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development of innovative robotic solutions for façade renovation. Within this framework, Gustave Eiffel University is developing a multi-physics non-destructive evaluation (NDE) probe, designed to be
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. Photoacoustic sensing (introductory video: https://youtu.be/2f3V0DQNLYg ) is based on a transformation of absorbed optical energy into ultrasound waves, when a transient optical excitation is used. The optical
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ultrasound, Laboratoire d'imagerie Biomedical, LIB , https://www.lib.upmc.fr/ ) and nanoparticle engineering ( PHENIX Laboratory https://phenix.cnrs.fr/ ). The LIB is located in the Centre de Recherche des
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reactions. The recruited QUANTASTIC PhD student will: -Contribute to the development of an experimental setup, -Develop and evaluate different kinetic models, including runaway scenarios, -Work in close
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conferences, workshops, and training events. High speed nanoindentation mapping (HSNM) is becoming very effective in evaluating the mechanical properties of materials from correlative measurements, such as
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-compatible measurement system using a coplanar waveguide architecture, assess their sensitivities, evaluate the possibilities of combining them, and test them with real biological samples—going beyond simple
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architecture combining perception, joint control, and quantitative evaluation of collaborative performance, with the objective of improving the fluency, safety, and efficiency of collaborative mobile
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-DFT, sTD-DFT, and TD-DFTB will be compared so as to evaluate the performances of the two latter. In this final step, the PhD student will use realistic systems coming from partners of the project
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together expertise in physics, chemistry, nanoscience, and materials engineering. For more information about IS2M, please feel free to visit the website: https://www.is2m.uha.fr/ . The PhD candidate (M/F