Topological surface states from ordered InBi crystals.

The ongoing research in topologically protected electronic states is driven not only by the obvious interest from a fundamental perspective but is also fueled by the promising use of these non-trivial states in energy technologies such as the field of spintronics. It is therefore important to find new materials exhibiting these compelling topological features. InBi has been known for many decades as a semi-metal in which Spin-Orbit Coupling (SOC) plays an important role. As SOC is a key ingredient for topological states, one may expect InBi to exhibit non-trivial states. Here we present a thorough analysis of InBi, grown on InAs(111)-A surface, by both experimental Angular-Resolved PhotoEmission Spectroscopy (ARPES) measurements and by fully-relativistic ab-initio electronic band calculations. Our investigation suggests the existence of topologically non-trivial metallic surface states and emphasizes the fundamental role of Bi within these electronic states. Moreover, InBi appears to be a topological crystalline insulator whose Dirac cones at the (001) surface are pinned at high-symmetry points. Consequently, as they are also protected by time-reversal symmetry, they can survive even if the in-plane mirror symmetry is broken at the surface.