Theory of AC Anomalous Hall Conductivity in d-electron systems

Abstract

To elucidate the intrinsic nature of anomalous Hall effect (AHE) in d-electron systems, we study the AC anomalous Hall conductivity (AHC) in a tight-binding model with (dxz,dyz)-orbitals. We drive a general expression for the AC AHC σxy(ω), which is valid for finite quasiparticle damping rate γ=/2τ, and find that the AC AHC is strongly dependent on γ. When γ=+0, the AC AHC shows a spiky peak at finite energy that originates from the interband particle-hole excitation, where represents the minimum band-splitting measured from the Fermi level. In contrast, we find that this spiky peak is quickly suppressed when γ is finite. By using a realistic value of γ(ω) at ω=/2 in d-electron systems, the spiky peak is considerably suppressed. In the present model, the obtained results also represents the AC spin Hall conductivity in a paramagnetic state.