Suchergebnisse

Under the terms of the Creative Commons Attribution License 3.0 (CC-BY). ; The intramolecular exchange interactions within the single-molecule magnet (SMM) "butterfly" molecule [Fe3Ln(μ3-O) 2(CCl3COO)8(H2O)(THF)3], where Ln(III) represents a lanthanide cation, are determined in a combined experimental [x-ray magnetic circular dichroism (XMCD) and vibrating sample magnetometer (VSM)] and theoretical work. Compounds with Ln=Gd and Dy, which represent extreme cases where the rare earth presents single-ion isotropic and uniaxial anisotropy, on one hand, and with Ln=Lu and Y(III) as pseudolanthanide substitutions that supply a nonmagnetic Ln reference case, on the other hand, are studied. The Dy single-ion uniaxial anisotropy is estimated from ab initio calculations. Low-temperature (T 2.5 K) hard x-ray XMCD at the Ln L 2,3 edges and VSM measurements as a function of the field indicate that the Ln moment dominates the polarization of the molecule by the applied field. Within the {Fe3LnO2} cluster the Ln-Fe3 subcluster interaction is determined to be antiferromagnetic in both Dy and Gd compounds, with values J Dy-Fe3=-0.4 K and J Gd-Fe3=-0.25 K, by fitting to spin Hamiltonian simulations that consider the competing effects of intracluster interactions and the external applied magnetic field. In the uniaxial anisotropic {Fe3DyO2} case, a field-induced reorientation of the Fe3 and Dy spins from an antiparallel to a parallel orientation takes place at a threshold field (μ0H=4 T). In contrast, in isotropic {Fe3GdO2} this reorientation does not occur. © 2013 American Physical Society. ; The financial support of Spanish MINECO Grant No. MAT2011-23791, the Alexander Von Humboldt Foundation (D.P.), and Aragonese DGA-IMANA E34 (cofunded by Fondo Social Europeo) and that received from European Union FEDER funds are also acknowledged. L.B.R. acknowledges the Spanish MINECO FPU 2010 grant. ; Peer Reviewed