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Information Eligibility criteria The candidate must: - Hold a PhD in microbiology or cell biology - Have significant experience in fluorescence microscopy: time-lapse, dynamic imaging, multi-channel, etc
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using imaging and behavior platforms at SPPIN. This project will allow the control of MeCP2 expression in order to optimize the efficacy of RTT gene therapy, while establishing a modular framework for
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using laser diagnostics, including: Flow visualization via Particle Image Velocimetry (PIV) Flame structure imaging via OH Planar Laser-Induced Fluorescence (PLIF) Wall temperature measurements via Laser
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. Non-destructive characterization using 3D imaging and diffraction techniques is one of MATEIS's key activities, carried out in close collaboration with the ID11 beamline (materials science) at
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research environment at the interface of biology, chemistry, and artificial intelligence. The project is led by a multidisciplinary team specialized in cell image analysis and multimodal modeling, providing
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carbon materials for therapeutic and preventive biomedical applications, and for imaging. The immobilization of bioactive molecules on carbon nanomaterials and other materials also allows their use as
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, paleopathologies, etc.), supervise/coordinate additional analyses (medical imaging, chemical, isotopic and DNA analyses, etc.) in collaboration with partner laboratories; - Contribute to the project's scientific
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techniques) - Fluorescence microscopy, data processing applied to image analysis - Basic mathematical skills (proportionality rules) + statistical analysis - Knowledge of molecular mechanisms of bacterial
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orbital character of electrons in the resulting spin-orbit torques. Activities: - magneto-transport in metallic and magnetic oxide heterostructures subjected to microwaves - magneto-optical imaging
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PhD on 2D quantum photonics : towards neuromorphic applications with 2D ferroelectrics materials M/F
-of-plane ferroelectric domains. The goal of this PhD is to optically detect, track, and ultimately control the ferroelectric state in such materials. Key objectives include imaging ferroelectric domains in a