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matter at very low energies. The data consist of high-resolution pixelated images, enabling detailed characterization of energy deposits in silicon. Novel analysis techniques (clustering, signal/background
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prototype designed at IEM Montpellier. The work will be conducted in collaboration with a postdoctoral researcher affiliated with the Paris Institute of Molecular Chemistry (IPCM, Sorbonne University), under
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at the interface between fluid mechanics and cell biology, within a laboratory affiliated with CNRS and Aix-Marseille University. The project relies on experimental platforms in microfluidics and advanced imaging
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or immunology and be committed to interdisciplinary research. Skills in cell biology, biochemistry, advanced microscopy techniques, image and high dimensional data analysis would be valuable assets. Curiosity and
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synchrotron method: 2DµXRD imaging. We have recently demonstrated a proof of concept of this experiment4. The PhD aims at (a) increasing resolution of 2DµXRD imaging and (b) make this technique available
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Laboratoire INSERM UMR1311 Rouen Normandie Université | Rouen, Haute Normandie | France | 7 days ago
English (written and oral) is required for international communication • Bonus: Basic knowledge of bioinformatics (e.g., Python, R) or image analysis software (Imaris, ImageJ) is an asset Additional
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for cryo-electron microscopy (cryo-EM) data analysis, modeling conformational heterogeneity, and identifying optimal binding candidates, by integrating image analysis and docking across multiple structural
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violation (if it is non-zero), improving the accuracy of oscillation parameters, and testing the three-flavor paradigm. To do this, the world's most intense neutrino beam is being built at FNAL (Fermilab
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inside hadrons, and the emergence of gluon saturation at high energies. A central goal of the project is to build a three-dimensional picture of hadron structure, encoding both the longitudinal momentum
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and molecular function. The project will build on the MDSPACE image analysis software [2], and its application to characterising VCP/p97 dynamics [3], to analyse cryo‑electron microscopy (cryo-EM