Magnetically induced polarization in centrosymmetric bonds

Abstract

We reveal the microscopic origin of electric polarization P induced by noncollinear magnetic order. We show that in Mott insulators, such P is given by all possible combinations of position operators rij = (rij\, 0,rij0) and transfer integrals tij = (tij0,tij0) in the bonds, where rij\, 0 and tij0 are spin-independent contributions in the basis of Kramers doublet states, while rij0 and tij0 stem solely from the spin-orbit interaction. Among them, the combination tij0 rij0, which couples to the spin current, remains finite in the centrosymmetric bonds, thus yielding finite P in the case of noncollinear arrangement of spins. The form of the magnetoelectric coupling, which is controlled by rij0, appears to be rich and is not limited to the phenomenological law P εij × [ei × ej] with εij being the bond vector connecting the spins ei and ej. Using density-functional theory, we illustrate how the proposed mechanism work in the spiral magnets CuCl2, CuBr2, CuO, and α-Li2IrO3, providing consistent explanation to available experimental data.