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to develop chiral metal nanoclusters, understand their chirality at the atomic level through a combination of advanced spectroscopic techniques and theoretical simulations, and apply them to relevant processes
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metal in the space between the NDs) or networks of 2D metal pads formed on the domains. Our team has good experience in the formation of hybrid nano-objects (organo-metallic) on the surface of water by
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-individual differences through a comparative approach in order to identify key, fundamental elements that are conserved or converge during evolution. To this end, we specifically intend to study the strategies
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for manufacturing chiral metal nanoclusters of different sizes, metal compositions and degrees of chirality (intrinsic and induced). The main objective of the work is to adjust the chiral properties in order to
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heat pump systems. The thermodynamic innovation of the project is based on the use of a fluid capable of undergoing a chemical dimerisation reaction, allowing a chemical energy component to be integrated
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the majority of polluting ionic species, as well as toxic heavy metal ions (Pb2+). The multiplexed detection system proposed for the study is based on the cointegration of several sensors that are selectively
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formation machinery (Grey, Baudat, de Massy 2018). Interestingly, in organisms, where PRDM9 is absent, or in mutant mice for PRDM9, DSBs still form, but they localize at functional genomic elements (FE) such
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to develop chiral metal nanoclusters, understand their chirality at the atomic level through a combination of advanced spectroscopic techniques and theoretical simulations, and apply them to relevant processes
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bodies moving in a fluid or fluids being transported in ducts and pipes. There is significant pressure to reduce transport-related emissions, of which friction drag is a major constituent. On the other
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for manufacturing chiral metal nanoclusters of different sizes, metal compositions and degrees of chirality (intrinsic and induced). The main objective is to use the nanoclusters designed both as multiphoton imaging