Particle-hole asymmetry and quantum confinement effects on the magneto-optical response of topological insulator thin-films
Department
Physics
Document Type
Article
Publication Date
4-28-2022
Abstract
Intrinsically broken symmetries in the bulk of topological insulators (TIs) are manifested in their surface states. Despite particle-hole asymmetry in TIs, it has often been assumed that their surface states are characterized by a particle-hole symmetric Dirac energy dispersion. In this work, we demonstrate that the effect of particle-hole asymmetry is essential to correctly describe the energy spectrum and the magneto-optical response in TIs thin-films. In thin-films of TIs with a substantial degree of particle-hole symmetry breaking, such as Sb 2Te 3, the longitudinal optical conductivity displays absorption peaks arising from optical transitions between bulk and surface Landau levels for low photon energies. The transition energies between the bulk and surface Landau levels exhibit clearly discernable signatures from those between surface Landau levels due to their distinct magnetic field dependence. Bulk contributions to the magneto-optical conductivity in a TI thin-film are enhanced via one type of doping while being suppressed by the other. This asymmetric dependence on the type of doping aids in revealing the particle-hole asymmetry in TI thin-films.
Journal Title
Journal of Applied Physics
Journal ISSN
00218979
Volume
131
Issue
16
Digital Object Identifier (DOI)
10.1063/5.0087720