Abstract
Theoretical studies on M$_{13}$ (M = Fe, Co, Ni) and M$_{13}$Pt$_n$ (for $n$ = 3, 4, 5, 20) clusters including the spin-orbit coupling are done using density functional theory. The magnetic anisotropy energy (MAE) along with the spin and orbital moments are calculated for M$_{13}$ icosahedral clusters. The angle-dependent energy differences are modelled using an extended classical Heisenberg model with local anisotropies. From our studies, the MAE for Jahn-Teller distorted Fe$_{13}$, Mackay distorted Fe$_{13}$ and nearly undistorted Co$_{13}$ clusters are found to be 322, 60 and 5 $\mu$eV/atom, respectively, and are large relative to the corresponding bulk values, (which are 1.4 and 1.3 $\mu$eV/atom for bcc Fe and fcc Co, respectively.) However, for Ni$_{13}$ (which practically does not show relaxation tendencies), the calculated value of MAE is found to be 0.64 $\mu$eV/atom, which is approximately four times smaller compared to the bulk fcc Ni (2.7 $\mu$eV/atom). In addition, MAE of the capped cluster (Fe$_{13}$Pt$_4$) is enhanced compared to the uncapped Jahn-Teller distorted Fe$_{13}$ cluster.
Highlights
Small transition-metal clusters may be functionalized and used in magnetic nanometer devices
The exchange coupling in free Fe clusters was found to depend on the cluster size and on the position of the cluster atoms involved in a complex way with no obvious systematics.[1,2]
We have only considered the icosahedral symmetry of Co13 cluster for our studies but a layered hcp structure is found to be the ground state for this cluster.[40]
Summary
Small transition-metal clusters may be functionalized and used in magnetic nanometer devices. This requires knowledge of the expected spin and orbital magnetic moments as well as of magnetic anisotropy energies. With respect to magnetic properties, the variations in magnetic moments with cluster size and morphology do frequently not allow to establish a clear trend. It may be safely concluded that the local magnetic moments in the outer shells of clusters are enhanced, compared to the interior or to the corresponding bulk crystal.[3,4,5,6] This effect is due to the reduced atomic coordination at the surface and is well confirmed by experiment.[7] Regarding the influence of structure, an analysis of cluster morphologies, by both experiment and theory,[8,9,10,11,12,13,14] reveals the importance of geometries with icosahedral symmetry, prohibited in periodic structures. The diversity of cluster structures in combination with the surface enhancement of magnetic moments make clusters interesting model objects for tuning magnetic properties at the nanometer scale.[15]
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