Topological Dirac semimetal phases in InSb/α-Sn semiconductor superlattices

Abstract

We demonstrate theoretically the coexistence of Dirac semimetal and topological insulator phases in InSb/α-Sn conventional semiconductor superlattices, based on advanced first-principles calculations combined with low-energy k· p theory. By proper interfaces designing, a large interface polarization emerges when the growth direction is chosen along [111]. Such an intrinsic polarized electrostatic field reduces band gap largely and invert the band structure finally, leading to emerge of the topological Dirac semimetal phase with a pair of Dirac nodes appearing along the (111) crystallographic direction near the point. The surface states and Fermi arc are clearly observed in (100) projected surface. In addition, we also find a two-dimensional topological insulator phase with large nontrivial band gap approaching 70 meV, which make it possible to observe the quantum spin Hall effect at room temperature. Our proposal paves a way to realize topological nontrivial phases coexisted in conventional semiconductor superlattices by proper interface designing.