Characterizing the chemical potential disorder in the topological insulator (Bi1-xSbx)2Te3 thin films
Abstract
We use scanning tunneling microscopy and spectroscopy under ultra-high vacuum and down to 1.7 K to study the local variations of the chemical potential on the surface of the topological insulator (Bi1-xSbx)2Te3 thin films (thickness 7 - 30 nm) with varying Sb-concentration x, to gain insight into the charge puddles formed in thin films of a compensated topological insulator. We found that the amplitude of the potential fluctuations, , is between 5 to 14 meV for quasi-bulk conducting films and about 30 - 40 meV for bulk-insulating films. The length scale of the fluctuations, λ, was found to span the range of 13 - 54 nm, with no clear correlation with . Applying a magnetic field normal to the surface, we observe the condensation of the two-dimensional topological surface state into Landau levels and find a weak but positive correlation between and the spectral width of the Landau-level peaks, which suggests that quantum smearing from drift motion is the source of the Landau level broadening. Our systematic measurements give useful guidelines for realizing (Bi1-xSbx)2Te3 thin films with an acceptable level of potential fluctuations. In particular, we found that x≈ 0.65 realizes the situation where shows a comparatively small value of 14 meV and the Dirac point lies within 10 meV of the Fermi energy.
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