Photo-Induced Topological Phase Transition and a Single Dirac-Cone State in Silicene

Abstract

Silicene (a monolayer of silicon atoms) is a quantum spin Hall insulator (QSHI), which undergoes a topological phase transition to a band insulator under external electric field Ez. We investigate a photo-induced topological phase transition by irradiating circular polarized light at fixed Ez. The band structure and also the topological property are modified by photon dressing. By increasing the intensity of light at Ez=0 , a photo-induced quantum Hall insulator (P-QHI) is realized, where the quantum Hall effect occurs without magnetic field. Its edge modes are anisotropic chiral, in which the velocities of up and down spins are different. There appears a spin polarized metal characterized by topological flat bands at the critical point between the QSHI and P-QHI. At Ez>Ecr with a certain critical field Ecr, a photo-induced spin-polarized quantum Hall insulator emerge. This is a new state of matter, possessing one Chern number and one half spin-Chern numbers. The edge mode supports a perfectly spin-polarized current, which are different from the chiral or helical edge modes. We newly discovered a single Dirac-cone state along a phase boundary. A distinctive hallmark of the state is that one of the two Dirac valleys is closed with a linear dispersion and the other open with a parabolic dispersion.