Preparation of Monodisperse Luminescent Particles of Y2-xGdxO3:Eu by Microwave-assisted Hydrolysis

Development of energy-saving methods of synthesis of monodisperse particles of rare-earth oxides with improved luminescent properties is very vital task. In present work we’ve developed new method of microwave-assisted synthesis of Y2-xGdxO3:Eu solid solutions, performed a study of influence of Y:Gd ratio on morphology and luminescent properties of monodisperse oxide particles. We’ve established monotonous dependence of mean size of particles on Y:Gd ratio. On the other hand dependence of intensity of luminescence on Y:Gd ratio has a clear maximum. When you are citing the document, use the following link http://essuir.sumdu.edu.ua/handle/123456789/3490

Intrinsic and impurity luminescence of rare earth ions doped KYF4 nanophosphors

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Vacuum ultraviolet spectroscopic analysis of Ce3+-doped hexagonal YPO4·0.8H2O based on exchange charge model

The hexagonal YPO4·0.8H2O:Ce3+ nanophosphors are successfully prepared by the microwave–hydrothermal technique for the first time. The 4f–5d excitation spectrum of Ce3+ ion in the synthesized samples is recorded at 10 K using synchrotron radiation after the crystalline phase structure was confirmed by the X-ray diffraction(XRD) analysis. The combination of the effective Hamiltonian model for 5d1 configuration of Ce3+ ions and the exchange charge model of crystal-field (CF) theory is employed to analyze both the present electronic spectra measured by us and the case of the tetragonal crystalline powder sample of YPO4:Ce3+ reported by van Pieterson et al. (Phys. Rev. B: Condens. Matter. 65 (2002) 045113). The calculated 5d electronic energy levels of Ce3+ ions doped in two crystalline phases are in good agreement with the experimental results. The obtained CF strength parameters for both the cases suggest that Ce3+ ions in the hexagonal phase experience a stronger CF effect. In addition, the expansion technique of CF Hamiltonian along the chosen point-group chain is proposed to qualitatively understand the relationship between the local structure around Ce3+ impurities and the observed 5d energy splitting pattern for two cases