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7285 within the Catalysis and Unconventional Media team under the supervision of the scientific coordinator. The project will be carried out in close collaboration with IJLRA and LPP. The candidate will
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application to catalysis remains unexplored. Yet, optical control could revolutionise the way catalysis is performed. One exciting opportunity could be to use targeted light pulses to control the steps in
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of nanomaterials for applications in catalysis and energy. The student will be part of a dynamic team of 6 researchers and teacher-researchers and 6 PhD student. He/she will benefit from the equipment available in
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. The candidate will join the "Electrochemistry and Energy Conversion" team in the Catalysis and Materials department of the Institute of Chemistry and Processes for Energy, the Environment and Health (ICPEES
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chemistry (specializing in molecular chemistry) and/or a chemical engineering degree. The candidate should be motivated by organic synthesis methodology and homogeneous catalysis, and be able to use
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catalysts on electrodes, allowing for the benefits of homogeneous and heterogeneous catalysis to be combined. Methods and Materials: Inorganic synthesis, electrochemical characterization, catalytic reaction
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a joint approach combining simulation-based process design with experimental research on heterogeneous catalysis for the optimisation of ammonia production that would be compatible with the EU's 2050
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new class of optical probes for use in applications of catalysis and molecular recognition. Quantum confinement and plasmonic amplification in these luminescent objects allow one to simultaneously
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will be conducted at the CNRS within the Institute of Chemistry of Media and Materials of Poitiers (IC2MP - UMR CNRS 7285), in the "Catalysis and non-conventional media" team, under the responsability