Anatase phase stability and doping concentration dependent refractivity in codoped transparent conducting TiO2 films

Nb0.06Sn x Ti0.94-x O-2 ( x <= 0.3) thin films were grown by a pulsed-laser deposition method with varying Sn concentration. Through a combinatorial technique, we find that Sn concentration can reach a maximum of about x = 0.3 while maintaining the stable anatase phase and epitaxy. A doping concentration dependence of the refractivity is revealed, in which refractivity reduction at a wavelength of. = 500 nm is estimated to be 12.4% for Nb0.06Sn0.3Ti0.64O2 thin film. Sn doping induced band-gap blue shift can be contributed to the mixing of extended Sn 5s orbitals with the conduction band of TiO2. Low resistivity on the order of 10(-4) Omega cm at room temperature and high internal transmittance of more than 95% in the visible light region are exhibited for Nb0.06Sn x Ti0.94-x O2 thin films ( x <= 0.2). Optical and transport analyses demonstrate that doping Sn into Nb0.06Ti0.94O2 can reduce the refractivity while maintaining low resistivity and high transparency.