A commercial silicone resin (silicone) filled with ceramic nanoparticles has been employed for the preparation of mullite and β-SiAlON ceramics. Dense, pure, crack free mullite were prepared by the heating in air of a mixture of silicone resin and alumina nanoparticles in the temperature range 12001550 C. The high reactivity of Al2O3 towards silica, coupled with nanometric size, led to a large volume fraction of mullite crystals even at low firing temperatures (1250 C). β-SiAlON ceramics were prepared by the heating of a mixture of silicone resin and fillers consisting of Al2O3 nanoparticles and Si3N4 and AlN microparticles, in the temperature range 14501550 C in nitrogen atmosphere. The formation of SiAlON was found to be preceded by the formation of intermediate alumino-silicate phases like mullite and sillimanite, successively reduced (due to the carbon content of the ceramic residue of silicone resins) and nitrided. Although some oxide contamination was still present after the high temperature treatment, a high β-SiAlON yield (about 80%) was achieved. The use of nano-filled silicones provides a promising route for the fabrication of advanced ceramic components by exploiting polymer processing techniques, with the achievement of complex shapes

Advanced ceramics from a preceramic polymer and nano-fillers

BERNARDO, ENRICO;COLOMBO, PAOLO;
2009

Abstract

A commercial silicone resin (silicone) filled with ceramic nanoparticles has been employed for the preparation of mullite and β-SiAlON ceramics. Dense, pure, crack free mullite were prepared by the heating in air of a mixture of silicone resin and alumina nanoparticles in the temperature range 12001550 C. The high reactivity of Al2O3 towards silica, coupled with nanometric size, led to a large volume fraction of mullite crystals even at low firing temperatures (1250 C). β-SiAlON ceramics were prepared by the heating of a mixture of silicone resin and fillers consisting of Al2O3 nanoparticles and Si3N4 and AlN microparticles, in the temperature range 14501550 C in nitrogen atmosphere. The formation of SiAlON was found to be preceded by the formation of intermediate alumino-silicate phases like mullite and sillimanite, successively reduced (due to the carbon content of the ceramic residue of silicone resins) and nitrided. Although some oxide contamination was still present after the high temperature treatment, a high β-SiAlON yield (about 80%) was achieved. The use of nano-filled silicones provides a promising route for the fabrication of advanced ceramic components by exploiting polymer processing techniques, with the achievement of complex shapes
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11577/2442215
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