Spin-Flop Transition and Magnetocaloric Effect through Disconnected Magnetic Blocks in Co$^{III}$ /Co$^{IV}$ Oxybromides
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en
Article de revue
Ce document a été publié dans
Chemistry of Materials. 2010-05-28, vol. 22, n° 12, p. 3807-3816
American Chemical Society
Résumé en anglais
The magnetic properties of the layered Banþ1ConO3n-1Br (n=5 and 6) oxybromides have been determined by means of magnetization measurements and neutron diffraction under variable magnetic field. For n=6, the magnetic phase ...Lire la suite >
The magnetic properties of the layered Banþ1ConO3n-1Br (n=5 and 6) oxybromides have been determined by means of magnetization measurements and neutron diffraction under variable magnetic field. For n=6, the magnetic phase diagram has been built on the basis of several features, including the notions of short-range ordering, spin reorientation, and spin-flop transitions. In those compounds, the competition between magnetic exchanges arise from the existence of [Ba2O2Br]- double-layers that separate perovskite 2D-blocks. The latter are dominated by ferromagnetic (FM) intraexchanges while the interblock exchanges are antiferromagnetic (AFM). Interestingly, a perturbation created by an external magnetic field could be on the same order of magnitude than the interblock exchange leading to a complex set of spin reorientations versus H and T. From the point of view of magneto-crystalline anisotropy, theAFMsystem with moments parallel to the c-axis turns into a FM system with moments aligned in the perpendicular (a,b) planes. The magnetic entropy is distributed within at least three phenomena, spread out in a wide range of temperature. Here, the influence of the magneto-crystalline anisotropy on the magnetocaloric effect is unambiguously shown.< Réduire
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