Anisotropic optical properties of highly doped rutile SnO 2 : Valence band contributions to the Burstein-Moss shift

Abstract

The interband absorption of the transparent conducting semiconductor rutile stannic oxide (SnO 2 ) is investigated as a function of increasing free electron concentration. The anisotropic dielectric functions of SnO 2 :Sb are determined by spectroscopic ellipsometry. The onsets of strong interband absorption found at different positions shift to higher photon energies with increasing free carrier concentration. For the electric field vector parallel to the optic axis, a low energy shoulder increases in prominence with increasing free electron concentration. We analyze the influence of different many-body effects and can model the behavior by taking into account bandgap renormalization and the Burstein-Moss effect. The latter consists of contributions from the conduction and the valence bands which can be distinguished because the nonparabolic conduction band dispersion of SnO 2 is known already with high accuracy. The possible originsof the shoulder are discussed. The most likely mechanism is identified to be interband transitions at |k| > 0 from a dipole forbidden valence band.