Floquet-Driven Indirect Exchange Interaction Mediated by Topological Insulator Surface States

Light drives offer a potential tool for the dynamical control of magnetic interactions in matter. We theoretically investigate the indirect exchange coupling between two parallel chains of magnetic impurities on the surface of a topological insulator, driven by a time-periodic circularly polarized light field in the high-frequency, off-resonant, regime. We derive a closed-form analytic expression for the spin susceptibility of the photon-dressed topological insulator surface states and obtain the irradiation dependence of the Ising, Heisenberg, and Dzyaloshinsky-Moriya exchange couplings between the impurity chains. Our results show a two-pronged modification of these exchange couplings by periodic drives. First, the RKKY oscillation period of the exchange couplings can be extended by enhancing the driving strength. Secondly, increasing driving strength enhances the envelope of RKKY oscillations of the Heisenberg-type while suppressing those of the Ising-type and Dzyaloshinsky-Moriya-type. Our work provides useful insights for realizing Floquet engineering of collinear and non-collinear indirect exchange interactions in topological insulating systems.