Magneto-Infrared Spectroscopic Study of Ultrathin Bi2Te3 Single Crystals

Abstract

Ultrathin Bi2Te3 single crystals laid on Scotch tape are investigated by Fourier transform infrared spectroscopy at 4K and in a magnetic field up to 35T. The magneto-transmittance spectra of the Bi2% Te3/tape composite are analyzed as a two-layer system and the optical conductivity of Bi2Te3 at different magnetic fields are extracted. We find that magnetic field modifies the optical conductivity in the following ways: (1) Field-induced transfer of the optical weight from the lower frequency regime (<250cm-1) to the higher frequency regime (% >250cm-1) due to the redistribution of charge carriers across the Fermi surface. (2) Evolving of a Fano-resonance-like spectral feature from an anti-resonance to a resonance with increasing magnetic field. Such behavior can be attributed to the electron-phonon interactions between the % Eu1 optical phonon mode and the continuum of electronic transitions. (3) Cyclotron resonance resulting from the inter-valence band Landau level transitions, which can be described by the electrodynamics of massive Dirac holes.