Anomalous Hall Effect in Ferromagnetic Metals: Role of Phonons at Finite Temperature

Abstract

The anomalous Hall effect in a multiband tight-binding model is numerically studied taking into account both elastic scattering by disorder and inelastic scattering by the electron-phonon interaction. The Hall conductivity is obtained as a function of temperature T, inelastic scattering rate γ, chemical potential μ, and impurity concentration x imp. We find that the new scaling law holds over a wide range of these parameters; -σxy= (α σxx0-1 + β σxx0-2) σxx2 + b, with σμ (σμ 0) being the conductivity tensor (with only elastic scattering), which corresponds to the recent experimental observation [Phys. Rev. Lett. 103 (2009) 087206]. The condition of this scaling is examined. Also, it is found that the intrinsic mechanism depends on temperature under a resonance condition.