Four-band insulator on a Z2 domain wall: an analytically solvable model for the interface between trivial and topological 2D insulators

Abstract

A phenomenological model for the interface between trivial and topological two-dimensional insulators possessing the same band gap is presented. The model depends on three measurable parameters, the energy gap Eg, the Fermi velocity of the metallic edge states vF and the thickness of the interface where the gap inversion occurs, and can be reduced to the Schr\"odinger equation for the modified P\"oschl-Teller potential, which admits an analytical solution. It is demonstrated that the underlying physics is determined by the adimensional parameter α=Eg/2 vF, whose integral part determines the number of massive bound states at the interface. Furthermore, when α is exactly an integer, waves incident on the interface are never reflected. Results for parameters chosen in the typical scale of condensed matter systems are briefly discussed.