Comprendre les propriétés fonctionnelles des matériaux, couches minces et nanostructures nécessite de corréler leur structure à l’échelle nanométrique à leurs propriétés magnétiques. Pour atteindre cet objectif, la stratégie de l’équipe est de combiner des outils d’investigation classiques (diffraction des rayons X, SQUID et la mesure de couple par magnétométrie) avec des techniques avancées impliquant des développements internes: sondes locales (RMN pour matériaux ferromagnétiques, XMCD) ou imagerie (MET, MFM, holographie électronique). Les exemples sont des alliages anisotropes avec une application dans le stockage de l’information à haute densité, multicouches pour miroirs à rayons X, matériaux multiferroïques pour la spintronique, ou la sélection des nanoparticules par taille pour applications magnétiques et catalytiques. Le cas échéant, des méthodes d’analyse spécifiques sophistiquées (y compris des simulations de dynamique moléculaire) sont élaborées afin de mieux comprendre les observations.
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https://www.ipcms.fr/wp-content/plugins/zotpress/
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https://www.ipcms.fr/wp-content/plugins/zotpress/
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Facettage à l’échelle atomique dans les nanoparticules de CoPt épitaxiées sur NaCl
Transition dans Ce massif sous Pression
Couplage d’échange magnétique oscillant dans des multicouches Cobalt/Silicium déposées à 90 K
Dynamique de réseau et enthalpies de migration dans CoPt3 et FePd
Diversité des couplages magnétiques dans les multicouches d’oxydes
Films d’alliage anisotrope CoPt(110)
Films d’alliage magnétique anisotrope FeNiPt2
Dichroisme magnétique circulaire dans CeFe2 par diffusion inélastique de rayons x résonnante