화학공학소재연구정보센터
Powder Technology, Vol.346, 150-159, 2019
Photoluminescence properties and thermal stability of RE2-xEuxSn2O7 (RE = Y3+, Gd3+, Lu3+) red nanophosphors: An experimental and theoretical study
Defect-fluorite structured Eu3+-doped Y2Sn2O7 nanoparticles (30-40 nm) were successfully prepared through a facile co-precipitation method without any organic additives or templates followed by calcination in air. Luminescent properties of the as-prepared Y2-xEuxSn2O7 (0.02 <= x <= 0.6) nanophosphors were fully characterized from an experimental and theoretical point of view (excitation, emission, lifetime, critical concentration, temperature-dependent luminescence and thermal stability, type of interactions and the Judd-Ofelt analysis). The nanophosphors showed relatively sharp excitation bands from 360 to 530 nm and exhibited characteristic emission bands with the most intensive emission centered at 612 nm. In addition, Gd1.98Eu0.02Sn2O7 and Lu1.98Eu0.02Sn2O7 samples were prepared in order to study how substitution of RE3+ (Y3+ with Gd3+ and Lu3+ ions) influences on luminescent properties of RE1.98Eu0.02Sn2O7 and thermal stability of their luminescence. In order to understand better luminescent properties, the Judd-Ofelt analysis was applied to all the synthesized powders. The highest value of quantum efficiency, similar to 96%, was estimated for Lu1.98Eu0.02Sn2O7. To assess potential application in high-power LEDs, the temperature-dependent emission spectra of Y1.98Eu0.02Sn2O7. Gd1.98Eu0.02Sn2O7 and Lu1.98Eu0.02Sn2O7 nanophosphors were studied. (C) 2019 Elsevier B.V. All rights reserved.