Abstract:Zn-doped TiO₂ (Zn-TiO₂) thin films were prepared by the sol-gel method on titanium substrates with heat treatment at different temperatures. The effects of heat treatment temperatures and Zn doping on the structure, photocathodic protection and photoelectrochemical properties of TiO₂ thin films were investigated. It is indicated that the photoelectrical performance of the Zn-TiO₂ films is enhanced with the addition of Zn element compared with the pure-TiO₂ film and the largest decline by 897 mV in the electrode potential is achieved under 300 °C heat treatment. SEM-EDS analyses show that Zn element is unevenly distributed in Zn-TiO₂ films; XRD patterns reveal that the grain size of Zn-TiO₂ is smaller than that of pure-TiO₂; FTIR results indicate that Zn—O bond forms on Zn-TiO₂ surface. Ultraviolet visible absorption spectra prove that Zn-TiO₂ shifts to visible light region. Mott-Shottky curves show that the flat-band potential of Zn-TiO₂ is more negative and charge carrier density is bigger than that of pure-TiO₂, implying that under the synergy of the width of the space-charge layer, carrier density and flat-band potential, Zn-TiO₂ with 300 °C heat treatment displays the best photocathodic protection performance.

Key words: TiO₂ films; Zn-doping; photocathodic protection; photoelectrochemical activity; sol-gel method