First-principles study of a single-molecule magnet Mn12 monolayer on the Au(111) surface

Abstract

The electronic structure of a monolayer of single-molecule magnets Mn12 on a Au(111) surface is studied using spin-polarized density-functional theory. The Mn12 molecules are oriented such that the magnetic easy axis is normal to the surface, and the terminating ligands in the Mn12 are replaced by thiol groups (-SH) where the H atoms are lost upon adsorption onto the surface. This sulfur-terminated Mn12 molecule has a total magnetic moment of 18 μB in the ground state, in contrast to 20μB for the standard Mn12. The Mn12 molecular orbitals broaden due to the interaction of the molecule with the gold surface and the broadening is of the order of 0.1 eV. It is an order of magnitude less than the single-electron charging energy of the molecule so the molecule is weakly bonded to the surface. Only electrons with majority spin can be transferred from the surface to the sulfur-terminated Mn12 since the gold Fermi level is well above the majority lowest unoccupied molecular orbital (LUMO) but below the minority LUMO. The amount of the charge transfer is calculated to be 1.23 electrons, dominated by the tail in the electronic distribution of the gold surface. A calculation of level shift upon charging provides 0.28 electrons being transferred. The majority of the charge transfer occurs at the S, C, and O atoms close to the surface. The total magnetic moment also changes from 18 μB to 20 μB, due to rearrangements of the magnetic moments on the S and Mn atoms upon adsorption onto the surface. The magnetic anisotropy barrier is computed including spin-orbit interaction self-consistently in density-functional theory. The barrier for the Mn12 on the gold surface decreases by 6 K in comparison to that for an isolated Mn12 molecule.