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functional properties of various material classes. The institute's expertise is centered on analytical strategies, modeling, physico-chemical approaches, and detailed studies of structure and reactivity. IPREM
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topological phases. As their existence is guaranteed by the material's band structure, these states are said to be “topologically protected” in the sense that their existence is not directly affected by
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, and the field of research is wide open. This project aims to study new materials based on ferrimagnetic oxides whose spin properties respond to THz excitations both as active materials (e.g. for THz
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surface-chemistry trends across selected metals and their oxides. These data will support the construction of a machine-learning force field tailored to NHC–surface systems, enabling large-scale molecular
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charge/discharge cycles. The aim is to provide a unique tool to better understand the structure and evolution of interfaces/interphases in batteries, and thus, guide the design of more efficient and
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of surface acoustic waves coupled to a high mobility electron gas through the acoustoelectric effect, in view of developing non-linear integrated photonic-phononic circuits. We will use a well known material
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selectivity and permeability and ultrahigh water permeability combined with high salt rejection. The objective of this work is to construct atomistic models of MOFs/Polymers and Artificial Water-Channel
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. The project will build upon the laboratory's expertise in C–O bond activation, decarboxylation, and photoredox catalysis. The LCMCE brings together a team of molecular chemists with specialized skills in
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. The post-doctoral researcher will participate in its installation and evaluation. He will build an optical bench in free space between the fibre-optic bench and the fibres connected to the gravimeter. He