Discovery of highly spin-polarized conducting surface states in the strong spin-orbit coupling semiconductor Sb2Se3

Abstract

Majority of the A2B3 type chalcogenide systems with strong spin-orbit coupling, like Bi2Se3, Bi2Te3 and Sb2Te3 etc., are topological insulators. One important exception is Sb2Se3, where a topological non-trivial phase was argued to be possible under ambient conditions, but such a phase could be detected to exist only under pressure. In this Letter, we show that like Bi2Se3, Sb2Se3, displays generation of highly spin-polarized current under mesoscopic superconducting point contacts as measured by point contact Andreev reflection spectroscopy. In addition, we observe a large negative and anisotropic magnetoresistance in Sb2Se3, when the field is rotated in the basal plane. However, unlike in Bi2Se3, in case of Sb2Se3 a prominent quasiparticle interference (QPI) pattern around the defects could be obtained in STM conductance imaging. Thus, our experiments indicate that Sb2Se3 is a regular band insulator under ambient conditions, but due to it's high spin-orbit coupling, non-trivial spin-texture exists on the surface and the system could be on the verge of a topological insulator phase.