Electronic and optical properties of doped TiO2 by many-body perturbation theory.

Doping is one of the most common strategies for improving the photocatalytic and solar energy conversion properties of TiO2, hence an accurate theoretical description of the electronic and optical properties of doped TiO2 is of both scientific and practical interest. In this work, we use many-body perturbation theory techniques to investigate two typical n-type dopants, Niobium and Hydrogen, in TiO2 rutile. Using the GW approximation to determine band edges and defect energy levels, and the Bethe Salpeter equation for the calculation of the absorption spectra, we show that many body corrections are crucial for accurately describing the energy position of the impurity states and the band gap narrowing of the doped material. The defect energy levels appear as non-dispersive bands associated with localized states lying at 0.7 eV below the conduction bands. These states are also responsible for the appearance of low energy absorption peaks that enhance the solar spectrum absorption of rutile. The spatial distributions of the excitonic wavefunctions associated with these low energy excitations are very different for the two dopants, suggesting a larger mobility of photoexcited electrons in Nb-TiO2.