First-principle studies of spin-electric coupling in a \Cu3\ single molecular magnet

Abstract

We report on a study of the electronic and magnetic properties of the triangular antiferromagnetic \Cu3\ single-molecule magnet, based on spin density functional theory. Our calculations show that the low-energy magnetic properties are correctly described by an effective three-site spin s=1/2 Heisenberg model, with an antiferromagnetic exchange coupling J ≈ 5 meV. The ground state manifold of the model is composed of two degenerate spin S=1/2 doublets of opposite chirality. Due to lack of inversion symmetry in the molecule these two states are coupled by an external electric field, even when spin-orbit interaction is absent. The spin-electric coupling can be viewed as originating from a modified exchange constant δ J induced by the electric field. We find that the calculated transition rate between the chiral states yields an effective electric dipole moment d = 3.38× 10-33 C\ m ≈ e 10-4a, where a is the Cu separation. For external electric fields ≈ 108 V/m this value corresponds to a Rabi time τ ≈ 1 ns and to a δ J of the order of a few μeV.