Synthesis and luminescent properties of rare-earth-doped CeO2–CaF2 solid solutions via chemical solution routes

CeO2–CaF2 solid solutions were synthesized by a chemical solution method starting from metal acetates, trifluoroacetic acid as a fluorine source, and anhydrous ethanol as a solvent. Precursor gels, which were obtained by drying the resultant ethanolic solution at 110 °C, were heat-treated at a temperature in the range 400–1000 °C in air to obtain powdery products. Elemental analysis by energy dispersive X-ray spectroscopy and X-ray photoelectron spectroscopy revealed that heating products actually contained cerium, calcium, oxygen, and fluorine. According to X-ray diffraction analysis, possible reaction pathways under high-temperature treatments were considered as initial formation of fluorides (CeF3 and CaF2), subsequent oxidation of Ce3+ to Ce4+ in air, and final conversion to fluorite-type Ce–Ca–O–F solid solutions. Doping of Eu3+ or Sm3+ ions in the solid solutions led to occurrence of their characteristic photoluminescence due to intra-configurational f–f electronic transitions. Photo-excitation was achieved by irradiation with near ultraviolet light mainly through charge transfer from O2− to Ce4+ in the solid solutions and subsequent energy transfer to the doped ions. Spectral structures of photoluminescence suggested the occupation of Eu3+ or Sm3+ in Ce4+ sites with inversion symmetry in the solid solutions.

Rare-earth-doped CeO2–CaF2 solid solutions were synthesized by a chemical solution method starting from metal acetates, trifluoroacetic acid, and ethanol. Chemical composition, structure, and optical properties of the solid solutions were systematically studied.Figure optionsDownload as PowerPoint slideHighlights
► CeO2–CaF2 solid solutions were synthesized from chemical solutions.
► Metal acetates and trifluoroacetic acid were used as starting materials.
► Fluorine-rich solid solutions were obtained by heating precursors in air.
► Rare-earth-doping led to characteristic photoluminescence upon UV irradiation.