Pyrolysis Kinetics for the Conversion of a Polymer into an Amorphous Silicon Oxycarbide Ceramic

Sorarù, Gian Domenico; Pederiva, Luca; Latournerie, Jérôme; Raj, Rishi

doi:10.1111/j.1151-2916.2002.tb00432.x

Cited by 96 publications

(69 citation statements)

References 14 publications

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“…The averaged diameter of the spun fiber is 16.8 µm. The curing process of the spun fiber was performed by placing fiber bundles in a covered vat (800 cm 3 ) with 10ml of SiCl 4 or TiCl 4 in a Teflon dish for 1h. The curing procedure was performed in a glove bag with flowing nitrogen.…”

Section: Methodsmentioning

confidence: 99%

“…Such resins were used as binding agents for SiC and carbon black filler grains to produce SiC base dense or porous ceramics by molding, shaping and sintering [1]. On the other hand, abnormally high creep resistance of the simple Si-O-C amorphous was reported and analyzed in detail recently [2,3]. In the starting silicone resin precursors, we paid attention to a kind of the polymethylsilsesquioxane -like resin with low carbon content.…”

Section: Introductionmentioning

confidence: 99%

“…In this article, the properties and structure of the ceramic fibers derived from the melt-spun resin fiber will be described from the viewpoint of curing and pyrolysis conditions. The intrinsic cost of the resin fiber is low, because the starting monomer, CH 3 SiCl 3 , is a major sub product in a silicone industry based on the chemical reaction between metal silicon and CH 3 Cl. In addition, polymerization of CH 3 SiCl 3 does not require special reagents, like sodium or magnesium [6].…”

Section: Introductionmentioning

confidence: 99%

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Synthesis of SiOC Base Fibers from Silicone Resin with Low Carbon Content and Control of Surface Functionality by Metal Chloride Treatment in Vapor

Narisawa

Satoh

Sumimoto

et al. 2010

MSF

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Abstract. Melt spinnable silicone resin with a low carbon content was spun to fiber form with an averaged diameter of 16.8 µm. When the resin fiber was cured by SiCl 4 vapor and pyrolyzed at 1273K in inert atmosphere, Si-O-C fiber with smooth surface was obtained. The measured tensile strength was relatively low. The fiber, however, showed oxidation resistance during high temperature exposure under an air flow. When the fiber was cured by TiCl 4 with an increased vapor pressure at 313K, 40% mass gain was observed after the curing. SiO 2 -TiO 2 fiber was obtained by pyrolysis in an air flow, while SiOC-TiO 2 fiber was obtained by pyrolysis in an inert atmosphere. Structure of TiO 2 and the resulting fiber surface morphology strongly depended on the temperature and the atmosphere during the pyrolysis.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Synthesis of SiOC Base Fibers from Silicone Resin with Low Carbon Content and Control of Surface Functionality by Metal Chloride Treatment in Vapor

Narisawa

Satoh

Sumimoto

et al. 2010

MSF

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“…The heat treatment allows for the conversion of polysiloxane to silicon oxycarbide in the specimens. 21) The composition of SiOC after pyrolysis at 1400°C was SiO 1.50 C 0.68 . 22) The pyrolyzed specimens were further heat-treated in argon to 1450°C for 1 h at a heating rate of 10°C/min and subsequently annealed at 18001950°C for the liquid-phase sintering of SiC using Al 2 O 3 and Y 2 O 3 .…”

Section: Methodsmentioning

confidence: 99%

Effect of filler addition on porosity and strength of polysiloxane-derived porous silicon carbide ceramics

Kumar

Eom

Kim

2011

J. Ceram. Soc. Japan

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Polycarbosilane (PCS) or silicon carbide (SiC) fillers were used as fillers in fabricating partially interconnected, open-cell porous SiC ceramics by carbothermal reduction of polysiloxane-derived SiOC and subsequent sintering process. The effects of filler type (PCS or SiC), filler content (050 mass %) and sintering temperature (18001950°C) on microstructure, porosity, and strength of the polysiloxane-derived porous SiC ceramics were investigated. The spherical pore morphology was retained with SiC filler addition, while irregular cells were dominant with PCS filler addition after sintering at low temperatures. The pore morphology became mostly irregular while the grain morphology changed from a mixture of small, equi-axed grains and large faceted grains to the large faceted grains with increase in sintering temperature from 1800 to 1950°C. Porosity decreased and strength increased with increase in sintering temperature irrespective of the filler source and content. PCS filler addition continuously increased the porosity and decreased the strength, whereas the porosity decreased and strength increased beyond 30 mass % SiC filler addition in the starting composition. Less strength was recorded for the ceramics prepared with PCS fillers. It was possible to adjust the porosity from 34 to 59% and flexural strength from 16 to 96 MPa by controlling the filler type, filler content, and sintering temperature.

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“…[8] The transformation of polysiloxanes [RSiO 3/2 ] carrying hydrocarbon groups (R = methyl, phenyl, vinyl) in an inert atmosphere is well investigated and results in the formation of an amorphous silicon oxycarbide (SiOC, 800-1000°C), which decomposes to a ceramic consisting of SiC, SiO 2 and graphite at higher temperatures (1400-1500°C). [9][10][11][12] There are many examples, where a combination of a polysiloxane with a metal or a metal salt was used to prevent shrinkage, crack and pore formation of the resulting dense ceramic following the active filler controlled polymer pyrolysis concept (AFCOP). [2,13,14] Other groups used metal salts to introduce electrical conductivity or magnetic properties to SiOC materials [15] or investigated the Ni catalysed formation of carbon nanotubes in the resulting ceramics, which was observed applying temperatures beyond 800°C.…”

mentioning

confidence: 99%

Synthesis and Properties of Porous Hybrid Materials containing Metallic Nanoparticles

et al. 2008

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The pyrolysis of preceramic polymers like polysiloxanes provides the possibility of manufacturing ceramics at lower temperatures (500-1500°C) compared to the powder sintering route and of using versatile polymer shaping routes, what has attracted a growing attention in the last decade. [1] Ceramic products with different structures and functions (e.g. bulk materials, [2] composites, [3] coatings [4] and foams [5] ) were manufactured by this route and their properties (e.g. oxidation and thermal resistance, [6] electrical conductivity [7] ) can be altered by tailoring the molecular structure of the precursor and by loading the polymer with filler particles. [8] The transformation of polysiloxanes [RSiO 3/2 ] carrying hydrocarbon groups (R = methyl, phenyl, vinyl) in an inert atmosphere is well investigated and results in the formation of an amorphous silicon oxycarbide (SiOC, 800-1000°C), which decomposes to a ceramic consisting of SiC, SiO 2 and graphite at higher temperatures (1400-1500°C). [9][10][11][12] There are many examples, where a combination of a polysiloxane with a metal or a metal salt was used to prevent shrinkage, crack and pore formation of the resulting dense ceramic following the active filler controlled polymer pyrolysis concept (AFCOP). [2,13,14] Other groups used metal salts to introduce electrical conductivity or magnetic properties to SiOC materials [15] or investigated the Ni catalysed formation of carbon nanotubes in the resulting ceramics, which was observed applying temperatures beyond 800°C. [16] The size of Ni nanoparticles (< 1 wt.%) formed during pyrolysis from methylphenyl polysiloxanenickel acetate precursor came up with average diameters of 40-60 nm.A partial conversion of polysiloxane precursors below 800°C yields novel hybrid materials, which often exhibit high porosities and are therefore considered to be potential materials for adsorption and for catalyst supports. However, an adjusted design or functional testing of these hybrid materials in terms of sorption behaviour or catalytic activity has only been performed in far cases. [17] The current study focuses on the use of Ni and Pt containing polysiloxanes for preparation of highly porous hybrid materials (so called "ceramers") by inert gas pyrolysis (400-600°C) for use as adsorbent and as catalyst. In order to realize a homogeneous distribution of metallic particles at high metal contents 3-aminopropyltriethoxysilane was used for complexation of metal ions also in the combination with varying amounts of phenyltriethoxysilane. At the same time it was of interest how the different polarity of the siloxanes used for precursor preparation influenced the surface characteristic (hydrophilic/hydrophobic) of the resulting ceramers. These surface characteristics were examined in sorption experiments and first catalytic measurements revealed the catalytic activity of these ceramers. Experimental Synthesis of Polysiloxane Precursors and Processing of CeramersFor the synthesis of metal containing polysiloxane precursors 3-aminopropyltr...

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Pyrolysis Kinetics for the Conversion of a Polymer into an Amorphous Silicon Oxycarbide Ceramic

Cited by 96 publications

References 14 publications

Synthesis of SiOC Base Fibers from Silicone Resin with Low Carbon Content and Control of Surface Functionality by Metal Chloride Treatment in Vapor

Synthesis of SiOC Base Fibers from Silicone Resin with Low Carbon Content and Control of Surface Functionality by Metal Chloride Treatment in Vapor

Effect of filler addition on porosity and strength of polysiloxane-derived porous silicon carbide ceramics

Synthesis and Properties of Porous Hybrid Materials containing Metallic Nanoparticles

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