Effect of indium ion implantation on crystallization kinetics and phase transformation of anodized titania nanotubes using in-situ high-temperature radiation diffraction

摘要

Titania nanotube arrays were synthesized electrochemically by anodization of titanium foils, and the synthesized titania nanotubes were then implanted with indium ions. The effect of In-ions implantation on crystallization and phase transformation of titania was investigated using in-situ high-temperature X-ray diffraction and synchrotron radiation diffraction from room temperature to 1000 ℃. Diffraction results show that crystalline anatase first appeared at 400 ℃ in both the non-implanted and the In-implanted materials. The temperature at which crystalline rutile temperature appeared was 600 ℃ for non-implanted materials and 700 ℃ for In-implanted materials, and the indium implantation inhibited the anatase-to-rutile transformation. Although In~(3+) is expected to increase oxygen vacancy concentration and then the rate of titania transformation, the observations are consistent with implanted In-ions occupying the Ti sublattice substitutionally and then inhibiting the transformation. The relatively difficult anatase-to-rutile transformation in the In-implanted material appears to result from the relatively large In~(3+) radius (0.080 nm). The In~(3+) partly replaces the Ti~(4+) (0.061 nm), which provides a greater structural rigidity and prevents relaxation in the Ti bonding environment.