Photoluminescence of samarium-doped TiO2 nanotubes

Samarium (Sm)-modified TiO2 nanotubes (TNTs) were synthesized by low-temperature soft chemical processing. X-ray powder diffraction analyses of the synthesized Sm-doped and non-doped TNTs show a broad peak near 2θ=10°, which is typical of TNTs. The binding energy of Sm 3d5/2 for 10 mol% Sm-doped TNT (1088.3 eV) was chemically shifted from that of Sm2O3 (1087.5 eV), showing that Sm existed in the TiO2 lattice. Sm-doped TNTs clearly exhibited red fluorescence, corresponding to the doped Sm3+ ion in the TNT lattice. The Sm-doped TNT excitation spectrum exhibited a broad curve, which was similar to the UV–vis optical absorption spectrum. Thus, it was considered that the photoluminescence emission of Sm3+-doped TNT with UV-light irradiation was caused by the energy transfer from the TNT matrix via the band-to-band excitation of TiO2 to the Sm3+ ion.

Graphical AbstractSamarium-doped TiO2 nanotubes (TNTs) having a nanotubular structure were synthesized by soft chemical route. It was revealed that the energy associated by the band-to-band excitation of TNT matrix transferred to the doped Sm3+ ions in the lattice, resulting in emission of strong and visible red fluorescence.Figure optionsDownload as PowerPoint slideHighlights
► Sm-doped TiO2 nanotubes synthesized by low-temperature soft chemical processing.
► Sm3+ substitutes Ti4+ ions in the nanotube lattice.
► Clear fluorescent emission due to the f–f transition at the Sm3+ in a crystal field environment.
► Band-to-band excitation of TiO2 and followed energy transfer to Sm3+ causes the luminescence.