The NaYF4:yb3+,Tb3+ (Xyb: 0.20, XTb: 0.04) materials were prepared using the co-precipitation method, lne as-preparea material was washed either with or without water in addition to ethanol and thereafter annea...The NaYF4:yb3+,Tb3+ (Xyb: 0.20, XTb: 0.04) materials were prepared using the co-precipitation method, lne as-preparea material was washed either with or without water in addition to ethanol and thereafter annealed for 5 h at 500℃. This resulted in materials with moderate or very high up-conversion luminescence intensity, respectively. The structural study carried out with X-ray powder diffraction revealed microstrains in the rare earth (R) sublattice that were relaxed for the material with very high up-conversion intensity thus decreasing energy losses. The local structural details were investigated with R LⅢ and Y K edge ex- tended X-ray absorption fine structure (EXAFS) using synchrotron radiation. Around 10 tool.% of the Yb3+ ions were found to occupy the Na site in the material with very high up-conversion intensity. These Yb species formed clusters with the Tb3+ ions occupying the regular Na/R sites. Such clustering enhanced the energy transfer between Yb3+ and Tb3+ thus intensifying the up-conversion emission.展开更多
The yellow emitting dysprosium oxysulfide (Dy2O2S) and dysprosium oxysulfate (Dy202SO4) compounds were prepared from the thermal decomposition of hydrated dysprosium sulphate. The materials were characterized by u...The yellow emitting dysprosium oxysulfide (Dy2O2S) and dysprosium oxysulfate (Dy202SO4) compounds were prepared from the thermal decomposition of hydrated dysprosium sulphate. The materials were characterized by using thermogravimetry (TG/DTG), X-ray powder diffraction (XRD), Fourier transform infrared (FTIR) and Raman spectroscopies. The thermal stability temperatures at around 1151 and 1313 K were determined for the Dy202S and Dy202SO4 materials, respectively. The photolumines- cence properties of the dysprosium oxysulfide were investigated, showing narrow emission bands assigned to the 4F9/2----*6HJ intracon- figurational transitions of the Dy3+ ion. The yellow emission color of this phosphor suggests that the Dy202S is a promising material for applications in LEDs.展开更多
基金Project supported by Palomaa-Erikoski foundation,Academy of Finland,Conselho Nacional de Desenvolvimento Cientifico e Tec-nológico(Brazil)Finnish Funding Agency for Technology and Innovation(TEKES),Nordic Energy Research(Oslo,Norway)the European Community's Seventh Framework Programme(FP7/2007-2013)(312284)
文摘The NaYF4:yb3+,Tb3+ (Xyb: 0.20, XTb: 0.04) materials were prepared using the co-precipitation method, lne as-preparea material was washed either with or without water in addition to ethanol and thereafter annealed for 5 h at 500℃. This resulted in materials with moderate or very high up-conversion luminescence intensity, respectively. The structural study carried out with X-ray powder diffraction revealed microstrains in the rare earth (R) sublattice that were relaxed for the material with very high up-conversion intensity thus decreasing energy losses. The local structural details were investigated with R LⅢ and Y K edge ex- tended X-ray absorption fine structure (EXAFS) using synchrotron radiation. Around 10 tool.% of the Yb3+ ions were found to occupy the Na site in the material with very high up-conversion intensity. These Yb species formed clusters with the Tb3+ ions occupying the regular Na/R sites. Such clustering enhanced the energy transfer between Yb3+ and Tb3+ thus intensifying the up-conversion emission.
基金Project supported by Higher Education Personnel Improvement Coordination(CAPES)the National Council for Scientific and Technological Development(CNPq)+2 种基金the Laboratory of Thermal Analysis Prof.Ivo Giolito(LATIG-USP)Laboratory of f-block Elements(Leb-f)USPInstitute of Low Temperature and Structure Research and the Polish Academy of Sciences
文摘The yellow emitting dysprosium oxysulfide (Dy2O2S) and dysprosium oxysulfate (Dy202SO4) compounds were prepared from the thermal decomposition of hydrated dysprosium sulphate. The materials were characterized by using thermogravimetry (TG/DTG), X-ray powder diffraction (XRD), Fourier transform infrared (FTIR) and Raman spectroscopies. The thermal stability temperatures at around 1151 and 1313 K were determined for the Dy202S and Dy202SO4 materials, respectively. The photolumines- cence properties of the dysprosium oxysulfide were investigated, showing narrow emission bands assigned to the 4F9/2----*6HJ intracon- figurational transitions of the Dy3+ ion. The yellow emission color of this phosphor suggests that the Dy202S is a promising material for applications in LEDs.
