Quantum Hall Effects in Silicene

Abstract

We investigate quantum Hall effects in silicene by applying electric field Ez parallel to magnetic field. Silicene is a monolayer of silicon atoms forming a two-dimensional honeycomb lattice, and shares almost every remarkable property with graphene. A new feature is its buckled structure, due to which the band structure can be controlled externally by changing Ez. The low energy physics of silicene is described by massive Dirac fermions, where the mass is a function of Ez and becomes zero at the critical field Ecr. We show that there are no zero energy states due to the Dirac mass term except at the critical electric field Ecr. Furthermore it is shown that the 4-fold degenerate zero-energy states are completely resolved even without considering Coulomb interactions. These features are highly contrasted with those in graphene, demonstrating that silicene has a richer structure. The prominent feature is that, by applying the electric field, we can control the valley degeneracy. As a function of Ez, Hall plateaux appear at the filling factors =0, 1, 2, 3,... except for the points where level crossings occur.