Studies on synthesis, structural and spectroscopic properties of rare earth oxosalts for applications as vacuum ultraviolet phosphors

The rare earth elements (RE) have figured in the academic scenario for over two centuries, being an integral part of most up-to-date developed technologies in several fields of expertise. Regarding the applications of luminescent materials over the last years, the unique spectroscopic properties of RE elements have made them almost irreplaceable in classic tricolor devices, such as compact fluorescent lamps or cathode ray tubes. Nevertheless, the advent of new visualization and lighting technologies, like the high-resolution compact displays and the elimination of mercury from fluorescent lamps, has stimulated scientists to investigate the synthesis and properties of RE-based phosphors. In this work, we have evaluated the processes available for the synthesis of nanostructured RE phosphates and vanadates capable of acting as phosphors under vacuum ultraviolet excitation, and conducted the structural and spectroscopic characterization of these materials. We used three strategies to prepare the solids: the polymeric precursor method (Pechini), precipitation into reverse microemulsions, the colloidal precipitations. These methods can be adapted to the synthesis requirements and enable the control of morphology, composition and particle aggregation, thus constituting highly efficient ways to obtain nanostructured RE phosphates and/or vanadates. We synthesized orthophosphates (REPO4), phosphovanadates (REP1-xVxO4), and core@shell structures (REVO4@REPO4) with different composition, to generate of red, green, and blue phosphors, as well as solids with upconversion emissions. We characterized the prepared compounds by X-ray diffractometry, electron microscopy, dynamic light scattering, thermal analysis, and vibrational and luminescence spectroscopies (emission/excitation, luminescence lifetimes, quantum yields, chromaticity, and Judd-Ofelt intensity parameters). (AU)