光谱学与光谱分析 |
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Luminescence Properties of Silane Coupling Agent Modified Stilbene 3 Doped Lead-Tin-Fluorophosphate Glass |
GU Mu1, ZHAO Zhi-wei1, LIU Xiao-lin1, NI Chen1, HUANG Shi-ming1, LIU Bo1, OUYANG Xiao-ping2 |
1. Laboratory of Waves & Microstructure Materials, Pohl Institute of Solid State Physics, Tongji University, Shanghai 200092, China 2. Northwest Institute of Nuclear Technology,Xi’an 710024, China |
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Abstract In the present work, the SnF2 powder was modified by silane coupling agent KBM403. The Fourier transform infrared spectrum (FTIR) of the modified powder showed that KBM403 was absorbed on the surface of SnF2 particles through physical absorption besides a weak chemical absorption. Then the SnF2 powder was modified by the solution dissolved with stilbene 3. The modified SnF2 powder could improve the decentralization of stilbene 3 dopant. An organic-inorganic hybrid luminescence glass was prepared by doping the modified SnF2 powder with stilbene 3 into the low melting lead-tin-fluorophosphate (PTFP) glass. The excitation, emission and transmission (absorption) spectra were used to characterize the hybrid glass. The results showed that introducing KBM403 could improve solubility and decentralization of stilbene 3 in PTFP glass, reduce the concentration of stilbene 3 dimers, and increase the transparency and homogeneity of the glass. Meanwhile, the luminescence intensity of stilbene 3 in this hybrid glass increased evidently compared with that of the stilbene 3 doped glass. The effect was assumed to be the reduction of the quenching of luminescence from stilbene 3 dimer and the enhancement of the rigidity of stilbene 3 molecules due to the interaction between KBM403 and stilbene 3.
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Received: 2009-01-12
Accepted: 2009-04-18
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Corresponding Authors:
GU Mu
E-mail: mgu@tongji.edu.cn
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