Electronic transport and the related anomalous effects in silicene-like hexagonal lattice

Abstract: We investigate the anomalous effects due to the Berry correction and the considerable perturbations in the silicene-like hexagonal lattice system. The Berry curvature in periodic Bloch band system which related to the electromagnetic field is explored, the induced transverse anomalous velocity gives rise to the intrinsic Hall conductivity (without the vertex correction) expecially in the quantum anomalous Hall phase. The quantum anomalous Hall effect which related to the anomalous velocity term is detected, including the band avoided corssing effect and the generated special band gap. %{Enlarged Galilean symmetry of anyons and the Hall effect} The topological spin transport is affected by the Berry curvature %{Topological spin transport of a relativistic electron} %{Anomalous direction for skyrmion bubble motion} and the spin-current-induced Skyrmion spin texture motion is contrasted between the quantum spin Hall effect and quantum anomalous Hall effect. Since silicene involving the orbital degree of freedom, the orbital magnetic moment and orbital magnetization contributes significantly to the electronic transport properties of silicene %{Photoinduced quantum spin and valley Hall effects, and orbital magnetization in monolayer MoS2} as explored in this article. We also investigate the electronic tunneling properties of silicene in Josephon junction with the electric-field-induced Rashba-coupling, the anomalous effect due to the Berry phase is mentioned. Our results is meaningful to the application of the spintronics and valleytronics base on the silicene-like topological insulators.