Low-Energy Magnetic States of Tb Adatom on Graphene

Abstract

Electronic structure and magnetic interactions of a Tb adatom on graphene are investigated from first principles using combination of density functional theory and multiconfigurational quantum chemistry techniques including spin-orbit coupling. We determine that the six-fold symmetry hollow site is the preferred adsorption site and we investigate electronic spectrum for different adatom oxidation states including Tb3+, Tb2+, Tb1+, and Tb0. For all charge states, the Tb 4f8 configuration is retained with other adatom valence electrons being distributed over 5dxy, 5dx2+y2, and 6s/5d0 single-electron orbitals. We find strong intra-site adatom exchange coupling that ensures that the 5d6s spins are parallel to the 4f spin. For Tb3+, the energy levels can be described by the J=6 multiplet split by the graphene crystal field. For other oxidation states, the interaction of 4f electrons with spin and orbital degrees of freedom of 6s5d electrons in the presence of spin-orbit coupling results in the low-energy spectrum composed closely lying effective multiplets that are split by the graphene crystal field. Stable magnetic moment is predicted for Tb3+ and Tb2+ adatoms due to uniaxial magnetic anisotropy and effective anisotropy barrier around 440 cm-1 controlled by the temperature assisted quantum tunneling of magnetization through the third excited doublet. On the other hand, in-plane magnetic anisotropy is found for Tb1+ and Tb0 adatoms. Our results indicate that the occupation of the 6s5d orbitals can dramatically affect the magnetic anisotropy and magnetic moment stability of rare earth adatoms.