Scanning tunneling spectroscopy of Dirac electrons in doped SnTe

SnTe has attracted interest both as a ferroelectric material and because it is a topological crystalline insulator with Dirac surface states. However, due to the propensity for Sn vacancies, the Dirac point is generally well above the Fermi level in as-grown SnTe crystals and therefore difficult to experimentally access. Here we study doped SnTe samples using a scanning tunneling microscope. Quasi-particle interference measurements reveal the surface state dispersion and show that the Dirac point is shifted closer to the Fermi level. We further explore the behavior of these Dirac electrons in the presence of a magnetic field. This regime is particularly interesting in SnTe because it has multiple degenerate valleys, each of which lacks two-fold rotational symmetry. Therefore, valley polarized electronic states at odd integer filling factors are anticipated to possess an in-plane dipole moment, giving rise to a quantum Hall ferroelectric phase.