The preparation of Sn-doped SiO2 glasses with different Sn contents (Sn/(SiO2 + SnO2) ratio 0.01 to 10.0% w/w) was performed by two sol-gel routes. The first route (method A) used tin(IV) tert-butoxide as the tin precursor and in the presence of acetylacetone it resulted in transparent glasses with a maximum tin content of 0.1%. The precursor in the second route (method B) was dibutyltin diacetate; this was more efficient and transparent glasses of up to 1% tin content were obtained. As electron paramagnetic resonance can identify paramagnetic E' Sn centres, defects that form when silica glass is subjected to X-ray irradiation, we assessed the tin centres that substituted silicon in the silica network. At higher tin contents (Sn greater than or equal to 3%), method B gave crystalline nanosized particles of SnO2 (6-10 nm) dispersed throughout the silica matrix.
Chiodini, N., Morazzoni, F., Paleari, A., Scotti, R., Spinolo, G. (1999). Sol-gel synthesis of monolithic tin-doped silica glass. JOURNAL OF MATERIALS CHEMISTRY, 9(10), 2653-2658 [10.1039/a904415i].
Sol-gel synthesis of monolithic tin-doped silica glass
CHIODINI, NORBERTO;MORAZZONI, FRANCA;PALEARI, ALBERTO MARIA FELICE;SCOTTI, ROBERTO;SPINOLO, GIORGIO MARIO
1999
Abstract
The preparation of Sn-doped SiO2 glasses with different Sn contents (Sn/(SiO2 + SnO2) ratio 0.01 to 10.0% w/w) was performed by two sol-gel routes. The first route (method A) used tin(IV) tert-butoxide as the tin precursor and in the presence of acetylacetone it resulted in transparent glasses with a maximum tin content of 0.1%. The precursor in the second route (method B) was dibutyltin diacetate; this was more efficient and transparent glasses of up to 1% tin content were obtained. As electron paramagnetic resonance can identify paramagnetic E' Sn centres, defects that form when silica glass is subjected to X-ray irradiation, we assessed the tin centres that substituted silicon in the silica network. At higher tin contents (Sn greater than or equal to 3%), method B gave crystalline nanosized particles of SnO2 (6-10 nm) dispersed throughout the silica matrix.
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