Anomalous Hall effect, magneto-optical properties, and nonlinear optical properties of twisted graphene systems

Abstract

We study the anomalous Hall effect, magneto-optical properties, and nonlinear optical properties of twisted bilayer graphene (TBG) aligned with hexagonal boron nitride (hBN) substrate as well as twisted double bilayer graphene systems. We show that non-vanishing valley polarizations in twisted graphene systems would give rise to anomalous Hall effect which can be tuned by in-plane magnetic fields. The valley polarized states are also associated with giant Faraday/Kerr rotations in the terahertz frequency regime. Moreover, both hBN-aligned TBG and TDBG exhibit colossal nonlinear optical responses by virtue of the inversion-symmetry breaking, the small bandwidth, and the small excitation gaps of the systems. Our calculations indicate that in both systems the nonlinear optical conductivities of the shift currents are on the order of 103\,μA/V2; and the second harmonic generation (SHG) susceptibilities are on the order of 106\,pm/V in the terahertz frequency regime. Moreover, in TDBG with AB-BA stacking, we find that a finite orbital magnetization would generate a new component σxxx of the nonlinear photoconductivity tensor; while in AB-AB stacked TDBG with vertical electric fields, the valley polarization and orbital magnetization would make significant contributions to the σyxx component of the photoconductivity tensor. These nonlinear photo-conductivities are proportional to the orbital magnetizations of the systems, thus they are expected to exhibit hysteresis behavior in response to out-of-plane magnetic fields.