WO2012144638A1 - セラミックス焼結体及びセラミックス焼結体の製造方法 - Google Patents
セラミックス焼結体及びセラミックス焼結体の製造方法 Download PDFInfo
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- WO2012144638A1 WO2012144638A1 PCT/JP2012/060795 JP2012060795W WO2012144638A1 WO 2012144638 A1 WO2012144638 A1 WO 2012144638A1 JP 2012060795 W JP2012060795 W JP 2012060795W WO 2012144638 A1 WO2012144638 A1 WO 2012144638A1
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Definitions
- the present invention relates to a ceramic sintered body containing silicon carbide and aluminum nitride, and a method for producing the ceramic sintered body.
- Patent Document 1 a composite ceramic sintered body of silicon carbide and aluminum nitride has been used as a member constituting a semiconductor wafer manufacturing apparatus because it has excellent characteristics such as high strength and heat resistance (for example, Patent Document 1). reference).
- Ceramic sintered bodies generally have various characteristics that correlate with the bulk density. For this reason, a composite ceramic sintered body of silicon carbide and aluminum nitride having a large bulk density has been demanded.
- a composite ceramic sintered body of silicon carbide and aluminum nitride has a high thermal conductivity, so that the heat insulation is not excellent.
- an air layer called a pore has been provided so far to obtain a heat insulating effect, but a reduction in strength has been a problem. For this reason, there has been a demand for a composite ceramic sintered body of silicon carbide and aluminum nitride having good heat insulation.
- the present invention has been made in view of such a situation, and is a composite ceramic sintered body of silicon carbide and aluminum nitride having a large bulk density and good thermal insulation, and the manufacture of the ceramic sintered body. It aims to provide a method.
- a feature of the present invention includes silicon carbide and aluminum nitride, wherein the weight ratio of the aluminum nitride to the total weight ratio of the silicon carbide and the aluminum nitride is greater than 10% and not greater than 97%.
- the gist is that the bulk density is larger than 3.18 g / cm 3 .
- Another feature of the present invention is a method for producing a ceramic sintered body containing silicon carbide and aluminum nitride, comprising a silicon-containing raw material containing a liquid silicon compound, and an organic compound that generates carbon by heating.
- a step of mixing a carbon-containing raw material to be contained to produce a silicon carbide precursor, a step of heating and firing the silicon carbide precursor in an inert atmosphere to produce a silicon carbide raw material, and a hydrolyzable aluminum compound A step of mixing an aluminum-containing raw material containing carbon, a carbon-containing raw material containing an organic compound that generates carbon by heating, and water to produce an aluminum nitride precursor; and the aluminum nitride precursor in a nitrogen atmosphere.
- the summary is that the weight ratio of the aluminum nitride to the total weight ratio is larger than 10% and not larger than 97%.
- Another feature of the present invention is a method for producing a ceramic sintered body containing silicon carbide and aluminum nitride, comprising a silicon-containing raw material containing a liquid silicon compound and an organic compound that generates carbon by heating.
- the weight ratio of the aluminum nitride to the total weight ratio is larger than 10% and not larger than 97%.
- FIG. 1 is a flowchart for explaining a method of manufacturing a ceramic sintered body according to the first embodiment.
- Fig.2 (a) is a figure which shows the photograph of the surface of a silicon carbide ceramic sintered compact.
- FIG. 2B is a diagram showing a photograph of the surface of a ceramic sintered body (Example 1) in which the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride is 10.6%.
- FIG. 3 is a flowchart for explaining a method of manufacturing a ceramic sintered body according to the second embodiment.
- FIG. 4 is a graph of bulk density according to Examples and Comparative Examples.
- FIG. 5 is a graph of thermal conductivity according to examples and comparative examples.
- FIG. 1 is a flowchart for explaining a method of manufacturing a ceramic sintered body according to the first embodiment.
- Fig.2 (a) is a figure which shows the photograph of the surface of a silicon carbide ceramic sintered compact.
- FIG. 6 is a graph of bending strength according to the example and the comparative example.
- FIG. 7 is a graph of plasma resistance according to examples and comparative examples.
- FIG. 8 is data showing the results of XRD diffraction of the ceramic sintered bodies according to Example 9 and Comparative Examples 8 and 9.
- Ceramic sintered body The ceramic sintered body according to the present embodiment will be described.
- the ceramic sintered body contains silicon carbide and aluminum nitride.
- the bulk density of the ceramic sintered body is greater than 3.18 g / cm 3 .
- the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride is greater than 10% and 97% or less.
- the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride is obtained by dividing the weight ratio of aluminum nitride by the sum of the weight ratio of silicon carbide and the weight ratio of aluminum nitride ((AlN weight ratio) / ( SiC weight ratio + AlN weight ratio)).
- the thermal conductivity of the ceramic sintered body is preferably 65 W / mK or less.
- the thermal conductivity of the ceramic sintered body is more preferably 40 W / mK or less.
- the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride is preferably greater than 11% and 90% or less.
- the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride is preferably larger than 26% and not larger than 77%. This is because the ceramic sintered body satisfying this range has a thermal conductivity of 40 W / mK or less.
- the bulk density of the ceramic sintered body is preferably larger than 3.23 g / cm 3 .
- the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride is preferably 52% or more and 97% or less.
- the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride is more preferably larger than 76% and smaller than 96%. This is because the ceramic sintered body satisfying this range has a bulk density greater than 3.23 g / cm 3 and a plasma resistance of less than 10 ⁇ g / cm 2 .
- the ceramic sintered body is a rectangular parallelepiped having a length of 4 mm, a width of 3 mm, and a height of 26 mm, the distance between the spans is 20 mm and the crosshead speed is 5 mm / min.
- the bending strength is preferably 700 MPa or more.
- the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride is preferably greater than 10% and 76% or less.
- the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride is more preferably larger than 10% and smaller than 52%. This is because the ceramic sintered body satisfying this range has a bending strength of 700 MPa or more.
- the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride is preferably 27% or more and 97% or less.
- the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride is preferably greater than 51% and 96% or less. This is because the ceramic sintered body satisfying this range has a plasma resistance of less than 40 ⁇ g / cm 2 .
- the ceramic sintered body preferably contains yttrium oxide. Moreover, it is preferable that a ceramic sintered compact contains a phenol resin.
- the ceramic sintered body according to the present embodiment is mainly composed of silicon carbide and aluminum nitride. That is, the ceramic sintered body according to the present embodiment includes only silicon carbide and aluminum nitride, excluding the sintering aid and impurities.
- a composite ceramic sintered body of silicon carbide and aluminum nitride has excellent characteristics such as high strength and heat resistance. It has been used as a member constituting the apparatus.
- plasma is generated by introducing a high frequency in the presence of a halogen-based gas. Therefore, members existing in a space where plasma is generated, especially members holding a semiconductor wafer such as an electrostatic chuck and a susceptor, are easily affected by the plasma of the halogen gas, and are particularly corroded by the plasma of the halogen gas. Cheap.
- the composite ceramic sintered body of silicon carbide and aluminum nitride has high strength, the plasma resistance is not excellent. For this reason, when the composite ceramic sintered body of silicon carbide and aluminum nitride is used as a member constituting a semiconductor wafer manufacturing apparatus, there is a possibility that the quality of the semiconductor wafer is deteriorated by particles generated by corrosion.
- the method for producing a ceramic sintered body according to the present embodiment can provide a composite ceramic sintered body of silicon carbide and aluminum nitride that is particularly high in strength and excellent in plasma resistance.
- FIG. 1 is a flowchart for explaining a method of manufacturing a ceramic sintered body according to the present embodiment.
- the method for manufacturing a ceramic sintered body according to the present embodiment includes a raw material generation step S1, a mixing step S2, and a sintering step S3.
- the raw material generation step S1 is a step of generating a silicon carbide raw material and an aluminum nitride raw material.
- the silicon carbide raw material is generated by the silicon carbide precursor generation step S11a and the silicon carbide raw material generation step S12a.
- Silicon carbide precursor generation step S11a is a step of generating a silicon carbide precursor. First, a silicon-containing raw material containing a liquid silicon compound and a carbon-containing raw material containing an organic compound that generates carbon by heating are prepared.
- Silicon-containing raw material As a silicon-containing raw material containing a liquid silicon compound (hereinafter, appropriately referred to as a silicon source), the following liquid silicon compounds are used. A silicon source using not only a liquid silicon compound but also a solid silicon compound may be prepared.
- alkoxysilane mono-, di-, tri-, tetra-
- tetraalkoxysilane polymers are used as the liquid silicon compound.
- alkoxysilanes tetraalkoxysilane is preferably used. Specific examples include methoxysilane, ethoxysilane, propoxysilane, butoxysilane and the like. From the viewpoint of handling, ethoxysilane is preferable.
- the tetraalkoxysilane polymer include a low molecular weight polymer (oligomer) having a degree of polymerization of about 2 to 15, and a silicic acid polymer having a higher degree of polymerization and a liquid silicon compound.
- Examples of solid silicon compounds that can be used in combination with these liquid silicon compounds include silicon oxide.
- Examples of silicon oxide include silica sol (a colloidal ultrafine silica-containing liquid containing OH groups and alkoxyl groups inside), silicon dioxide (silica gel, fine silica, quartz powder), and the like.
- silicon compounds from the viewpoints of homogeneity and handling properties, tetraethoxysilane oligomers and mixtures of tetraethoxysilane oligomers and fine powder silica are preferred.
- Carbon-containing raw materials As the carbon-containing raw material containing an organic compound that generates carbon by heating (hereinafter referred to as a carbon source as appropriate), the following organic compounds are used.
- a carbon-containing raw material it is synthesized using a catalyst that does not contain an impurity element, and is composed of one or more organic compounds that can be cured by heating and / or polymerization or crosslinking with a catalyst or a crosslinking agent. Monomers, oligomers and polymers are preferred.
- the carbon-containing raw material include curable resins such as phenol resins, furan resins, urea resins, epoxy resins, unsaturated polyester resins, polyimide resins, and polyurethane resins synthesized using a catalyst that does not contain an impurity element. Is mentioned.
- curable resins such as phenol resins, furan resins, urea resins, epoxy resins, unsaturated polyester resins, polyimide resins, and polyurethane resins synthesized using a catalyst that does not contain an impurity element.
- a resol type or novolac type phenol resin having a high residual carbon ratio and excellent workability is preferable.
- the resol type phenolic resin useful in the present embodiment is monovalent or 2 such as phenol, cresol, xylenol, resorcin, bisphenol A in the presence of a catalyst (specifically ammonia or organic amine) that does not contain an impurity element. It is produced by reacting a valent phenol with an aldehyde such as formaldehyde, acetaldehyde, or benzaldehyde.
- the organic amine used as the catalyst may be any of primary, secondary, and tertiary amines.
- dimethylamine, trimethylamine, diethylamine, triethylamine, dimethylmonoethanolamine, monomethyldiethanolamine, N-methylaniline, pyridine, morpholine and the like can be used.
- the novolak type phenolic resin useful in the present embodiment is a mixture of monovalent or divalent phenols and aldehydes similar to those described above, and acids containing no impurity elements (specifically, hydrochloric acid, sulfuric acid, p. -Toluenesulfonic acid or oxalic acid) can be used as a catalyst for the reaction.
- acids containing no impurity elements specifically, hydrochloric acid, sulfuric acid, p. -Toluenesulfonic acid or oxalic acid
- a conventionally well-known method can also be adopted for the production of the novolac type phenol resin. That is, 0.5 to 0.9 mole of aldehyde and 0.02 to 0.2 mole of an inorganic or organic acid not containing an impurity element are added to 1 mole of phenol and heated to 60 to 100 ° C. .
- the prepared silicon source and carbon source are mixed.
- a polymerization or crosslinking catalyst or a crosslinking agent for example, an aqueous maleic acid solution
- a polymerization or crosslinking catalyst or a crosslinking agent for example, an aqueous maleic acid solution
- the produced silicon carbide precursor may be dried using, for example, a hot plate.
- Silicon carbide raw material production step S12a is a step of producing a silicon carbide raw material by heating and baking the silicon carbide precursor in an inert atmosphere. Specifically, the silicon carbide precursor is heated and fired in an inert gas atmosphere to carbonize and silicify the silicon carbide precursor.
- the inert gas include vacuum, nitrogen, helium, and argon.
- the silicon carbide precursor is heated and fired to obtain a target silicon carbide raw material (hereinafter, appropriately referred to as silicon carbide powder).
- a target silicon carbide raw material hereinafter, appropriately referred to as silicon carbide powder.
- the heating temperature is about 1600 to 2000 ° C.
- the firing time is about 30 minutes to 3 hours.
- carbon contained in the silicon carbide precursor becomes a reducing agent, and the following reaction occurs.
- silicon carbide powder is obtained.
- a so-called decarburization treatment may be performed by heating the silicon carbide powder at a temperature of 700 ° C. using an atmospheric furnace.
- the silicon carbide powder may be pulverized using, for example, a jet mill so that the center particle size becomes 1 to 2 ⁇ m.
- a method for producing a silicon carbide powder described in the method for producing a single crystal in Japanese Patent Application Laid-Open No. 9-48605 previously filed by the applicant of the present application can be mentioned. That is, one or more selected from high-purity tetraalkoxysilane and tetraalkoxysilane polymer is used as a silicon source, and a high-purity organic compound that generates carbon by heating is used as a carbon source.
- the aluminum nitride raw material is produced by an aluminum nitride precursor production step S11b and an aluminum nitride raw material production step S12b.
- Aluminum nitride precursor production step S11b is a step of generating an aluminum nitride precursor. First, an aluminum-containing raw material containing a hydrolyzable aluminum compound and a carbon-containing raw material containing an organic compound that generates carbon by heating are prepared.
- An aluminum-containing raw material containing a hydrolyzable aluminum compound (hereinafter, appropriately referred to as an aluminum source) is a hydrolyzable aluminum compound.
- an aluminum source is a hydrolyzable aluminum compound.
- liquid aluminum alkoxide can be used as the hydrolyzable aluminum compound.
- Carbon-containing raw material can be used as the carbon-containing raw material containing an organic compound that generates carbon by heating.
- the same carbon source as that prepared to form the silicon carbide precursor may be used, or a different carbon source may be used.
- the hydrolyzate is aluminum hydroxide.
- a catalyst that promotes hydrolysis of the liquid aluminum compound may be added to the mixture.
- you may add the catalyst aqueous solution for example, maleic acid aqueous solution
- the hydrolysis proceeds with water as the solvent of the aqueous catalyst solution, so it is not necessary to add water directly to the mixture.
- the catalyst either an organic acid or an inorganic acid can be used.
- the produced aluminum nitride precursor may be dried using, for example, a hot plate.
- the aluminum nitride raw material production step S12b is a step of producing an aluminum nitride raw material by heating and firing the aluminum nitride precursor in a nitrogen atmosphere.
- the aluminum nitride precursor is subjected to carbonization treatment and nitridation reduction treatment by heating and baking the aluminum nitride precursor in a nitrogen atmosphere.
- the aluminum nitride precursor undergoes aluminum oxide to produce aluminum nitride according to the following reaction formula.
- the mixing ratio of the aluminum element and the carbon element can be determined based on the above reaction formula. That is, the Al / C ratio is 0.67. Each raw material is adjusted based on this ratio.
- the heating temperature is preferably about 1500 to 2000 ° C.
- the firing time is preferably about 30 minutes to 10 hours.
- the refined aluminum nitride powder is produced by the above process.
- so-called decarburization treatment may be performed by heating the aluminum nitride powder at a temperature of 700 ° C. using an atmospheric furnace.
- the silicon carbide powder may be pulverized using, for example, a jet mill so that the center particle size becomes 1 to 2 ⁇ m.
- the mixing step S2 is a step of mixing the silicon carbide raw material and the aluminum nitride raw material.
- the silicon carbide powder and the aluminum nitride powder obtained in the above-described step S1 are mixed to obtain a slurry-like mixture.
- the weight ratio of aluminum nitride to the total weight ratio of the silicon carbide raw material and the aluminum nitride raw material contained in the mixture of the silicon carbide raw material and the aluminum nitride raw material is greater than 10% and 97% or less.
- the weight ratio (silicon carbide / aluminum nitride) of the silicon carbide powder and the aluminum nitride powder contained in the mixture of the silicon carbide powder and the aluminum nitride powder is in the range of 75/25 or more and 90/10 or less. Thus, it is preferable to mix silicon carbide powder and aluminum nitride powder.
- the weight ratio of aluminum nitride to the total weight ratio of the silicon carbide raw material and the aluminum nitride raw material contained in the mixture of the silicon carbide raw material and the aluminum nitride raw material is preferably 10% or more and 51% or less.
- the slurry mixture can be prepared using water, lower alcohols such as ethyl alcohol, ethyl ether, acetone or the like as a solvent. It is preferable to use a solvent having a low impurity content. An antifoaming agent such as silicone can also be added.
- an organic binder may be added when a slurry-like mixture is produced from aluminum nitride powder and silicon carbide powder.
- the organic binder include polyacrylic acid resin, peptizer, and powder adhesive.
- a nitrogen-based compound is preferably used from the viewpoint of further increasing the effect of imparting conductivity.
- ammonia, polyacrylic acid ammonium salt, etc. are used suitably.
- the powder adhesive polyvinyl alcohol resin or the like is preferably used.
- the slurry mixture is mixed with a phenolic resin as a non-metallic sintering aid as a sintering aid for silicon carbide powder, and yttrium oxide (Y 2 O 3 ) as a sintering aid for aluminum nitride powder. It is preferable to add.
- a phenolic resin as a non-metallic sintering aid as a sintering aid for silicon carbide powder
- Y 2 O 3 yttrium oxide
- aluminum nitride powder aluminum nitride powder. It is preferable to add.
- the phenol resin a resol type phenol resin is preferable.
- the phenol resin that is a non-metallic sintering aid can be used by dissolving in an organic solvent. You may mix the solution of a nonmetallic sintering auxiliary agent, yttrium oxide, silicon carbide powder, and aluminum nitride powder.
- organic solvent lower alcohols such as ethyl alcohol and acetone can be selected.
- the obtained slurry mixture is dried, for example, on a hot plate. By drying, a mixed powder of silicon carbide powder and aluminum nitride powder can be obtained. If necessary, the mixed powder is sieved.
- Sintering process S3 is a process of sintering the mixture of a silicon carbide raw material and an aluminum nitride raw material. Specifically, a mixed powder of silicon carbide powder and aluminum nitride powder is placed in a mold and hot press sintered. The mold is pressed and heated at a surface pressure of 150 kg / cm 2 to 350 kg / cm 2 . The heating temperature is preferably 1700 ° C. to 2200 ° C. The inside of the heating furnace is an inert atmosphere.
- the ceramic sintered body according to the present embodiment can be manufactured.
- the ceramic sintered body according to the present embodiment includes only a composite of silicon carbide and aluminum nitride and a sintering aid, excluding impurities.
- a silicon carbide precursor generation step of generating a silicon carbide precursor by mixing a silicon source and a carbon source S11a, a silicon carbide precursor generation step S12a for heating and baking a silicon carbide precursor in an inert atmosphere to generate silicon carbide powder, an aluminum source, a carbon source, and water are mixed to generate an aluminum nitride precursor
- a sintering step S3 for sintering a mixed powder of silicon carbide powder and aluminum nitride powder is greater than 10% and not greater than 97%.
- the ceramic sintered body according to the present embodiment is produced by a general manufacturing method.
- the density is higher than that of a ceramic sintered body produced by mixing the silicon carbide powder and aluminum nitride.
- the ceramic sintered body according to the present embodiment has a bulk density greater than 3.18 g / cm 3 .
- FIG. 2A is a view showing a photograph of the surface of the silicon carbide ceramic sintered body. That is, it is a view showing a photograph of the surface of a silicon carbide ceramic sintered body not containing aluminum.
- the silicon carbide ceramic sintered body is manufactured using a silicon carbide powder produced by heating and firing a silicon carbide precursor as a raw material.
- FIG.2 (b) is a figure which shows the photograph of the surface of the ceramic sintered compact (Example 1 mentioned later) whose weight ratio of aluminum nitride with respect to the total weight ratio of silicon carbide and aluminum nitride is 10.6%. is there.
- silicon carbide is solid-phase sintered, a plurality of pores are generally formed in the silicon carbide ceramic sintered body (see FIG. 2A).
- a mixed powder in which silicon carbide powder and aluminum nitride powder are mixed is sintered. Since aluminum nitride undergoes liquid phase sintering, material diffusion proceeds, so that it is difficult to form pores. For this reason, in the ceramic sintered body of this embodiment, the number of holes is reduced and the size of the holes is also reduced (see FIG. 2B). Since plasma is worn from the portion where the holes are formed, the ceramic sintered body of the present embodiment having a small number of holes and small holes improves the plasma resistance. Moreover, since it becomes difficult to form a void
- the silicon carbide powder and the aluminum nitride powder of the present embodiment use a silicon carbide powder manufactured from a silicon carbide precursor and an aluminum nitride powder manufactured from an aluminum nitride precursor, And good dispersion.
- the silicon carbide powder and the aluminum nitride powder are mixed appropriately, it is difficult to form pores in the entire ceramic sintered body.
- the good dispersion the proportion of bonds generated between the silicon carbide powder and the aluminum nitride powder increases, and a denser ceramic sintered body can be obtained. For this reason, wear due to plasma is suppressed and strength is improved.
- the weight ratio of silicon carbide powder to aluminum nitride powder (silicon carbide / aluminum nitride) contained in the mixed powder of silicon carbide powder and aluminum nitride powder is 75/25 or more and 90/10 or less. It is preferable that it exists in the range.
- the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the mixture of the silicon carbide raw material and the aluminum nitride raw material is preferably larger than 10% and not larger than 51%. As the proportion of aluminum nitride increases, solid solution progresses, so that the grain growth of aluminum nitride becomes significant.
- the weight ratio of silicon carbide powder to aluminum nitride powder is in the range of 75/25 or more and 90/10 or less, or the total of silicon carbide and aluminum nitride contained in the mixture of silicon carbide raw material and aluminum nitride raw material
- the weight ratio of aluminum nitride is in the range of 75/25 or more and 90/10 or less, or the total of silicon carbide and aluminum nitride contained in the mixture of silicon carbide raw material and aluminum nitride raw material
- a composite ceramic sintered body of silicon carbide and aluminum nitride is known as a material having high strength. Since such a ceramic sintered body has high strength, for example, it is used as a member constituting a semiconductor manufacturing apparatus.
- the composite ceramic sintered body of silicon carbide and aluminum nitride has high strength, it has a high thermal conductivity and therefore does not have excellent heat insulation. For this reason, there has been a demand for a composite ceramic sintered body of silicon carbide and aluminum nitride having high strength and good heat insulation.
- the method for producing a ceramic sintered body according to the present embodiment can provide a composite ceramic sintered body of silicon carbide and aluminum nitride, which has particularly high strength and good heat insulation.
- FIG. 3 is a flowchart for explaining a method for manufacturing a ceramic sintered body according to the present embodiment.
- the method for manufacturing a ceramic sintered body according to the present embodiment includes a composite precursor generation step S101, a composite powder generation step S102, a mixing step S103, and a sintering step S104.
- the composite precursor generation step S101 is a step of generating a composite precursor. Specifically, a silicon-containing raw material, a carbon-containing raw material, an aluminum-containing raw material, and water are mixed to produce a composite precursor.
- a silicon-containing raw material containing a liquid silicon compound, a carbon-containing raw material containing an organic compound that generates carbon by heating, an aluminum-containing raw material containing a hydrolyzable aluminum compound, and water are prepared.
- the silicon-containing raw material, the carbon-containing raw material, and the aluminum-containing raw material are prepared by the method described later.
- the water may be an aqueous solution containing a catalyst.
- the prepared silicon-containing material, carbon-containing material, aluminum-containing material, and water are mixed.
- the mixing method is not limited, but in order to easily mix the silicon-containing raw material and the carbon-containing raw material to cause polymerization or a cross-linking reaction, the aluminum-containing raw material, the carbon-containing raw material, and water are mixed, In order to easily cause a condensation reaction between a hydrolyzate generated by hydrolysis of a liquid aluminum compound and a carbon source, the following method is preferred.
- a silicon-containing material and a carbon-containing material are mixed.
- a polymerization or crosslinking catalyst or crosslinking agent eg, aqueous maleic acid solution
- aqueous maleic acid solution e.g., aqueous maleic acid solution
- an aluminum-containing raw material and a carbon-containing raw material are mixed into the mixture.
- water is added to the mixture.
- a catalyst that promotes hydrolysis of the liquid aluminum compound may be added to the mixture.
- you may add the catalyst aqueous solution for example, maleic acid aqueous solution
- the hydrolysis proceeds with water as the solvent of the aqueous catalyst solution, so it is not necessary to add water to the mixture.
- the catalyst for promoting hydrolysis either an organic acid or an inorganic acid can be used.
- Silicon-containing raw material, carbon-containing raw material, and aluminum-containing material so that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the composite powder is greater than 11% and 90% or less. It is more preferable to adjust the amount of the raw material.
- a composite precursor is generated by mixing a silicon-containing raw material, a carbon-containing raw material, an aluminum-containing raw material, and water.
- the produced composite precursor may be dried using, for example, a hot plate.
- the composite precursor includes a silicon carbide precursor that produces silicon carbide by heating and firing in an inert atmosphere, and an aluminum nitride precursor that produces aluminum nitride by heating and firing in an inert atmosphere containing nitrogen. Are mixed.
- Silicon-containing raw material As a silicon-containing raw material containing a liquid silicon compound (hereinafter, appropriately referred to as a silicon source), the following liquid silicon compound is used. A silicon source using not only a liquid silicon compound but also a solid silicon compound may be prepared.
- alkoxysilane mono-, di-, tri-, tetra-
- tetraalkoxysilane polymers are used as the liquid silicon compound.
- alkoxysilanes tetraalkoxysilane is preferably used. Specific examples include methoxysilane, ethoxysilane, propoxysilane, butoxysilane and the like. From the viewpoint of handling, ethoxysilane is preferable.
- the tetraalkoxysilane polymer include a low molecular weight polymer (oligomer) having a degree of polymerization of about 2 to 15, and a silicic acid polymer having a higher degree of polymerization and a liquid silicon compound.
- Examples of solid silicon compounds that can be used in combination with these liquid silicon compounds include silicon oxide.
- Examples of silicon oxide include silica sol (a colloidal ultrafine silica-containing liquid containing an OH group and an alkoxyl group), silicon dioxide (silica gel, fine silica, quartz powder), and the like.
- silicon compounds from the viewpoints of homogeneity and handling properties, tetraethoxysilane oligomers and mixtures of tetraethoxysilane oligomers and fine powder silica are preferred.
- Carbon-containing raw material As the carbon-containing raw material containing an organic compound that generates carbon by heating (hereinafter, appropriately referred to as a carbon source), the following organic compounds are used.
- a carbon-containing raw material it is synthesized using a catalyst that does not contain an impurity element, and is composed of one or more organic compounds that can be cured by heating and / or polymerization or crosslinking with a catalyst or a crosslinking agent. Monomers, oligomers and polymers are preferred.
- the carbon-containing raw material include curable resins such as phenol resins, furan resins, urea resins, epoxy resins, unsaturated polyester resins, polyimide resins, and polyurethane resins synthesized using a catalyst that does not contain an impurity element. Is mentioned.
- curable resins such as phenol resins, furan resins, urea resins, epoxy resins, unsaturated polyester resins, polyimide resins, and polyurethane resins synthesized using a catalyst that does not contain an impurity element.
- a resol type or novolac type phenol resin having a high residual carbon ratio and excellent workability is preferable.
- the resol type phenolic resin useful in the present embodiment is monovalent or 2 such as phenol, cresol, xylenol, resorcin, bisphenol A in the presence of a catalyst (specifically ammonia or organic amine) that does not contain an impurity element. It is produced by reacting a valent phenol with an aldehyde such as formaldehyde, acetaldehyde, or benzaldehyde.
- the organic amine used as the catalyst may be any of primary, secondary, and tertiary amines.
- dimethylamine, trimethylamine, diethylamine, triethylamine, dimethylmonoethanolamine, monomethyldiethanolamine, N-methylaniline, pyridine, morpholine and the like can be used.
- the novolak type phenolic resin useful in the present embodiment is a mixture of monovalent or divalent phenols and aldehydes similar to those described above, and acids containing no impurity elements (specifically, hydrochloric acid, sulfuric acid, p. -Toluenesulfonic acid or oxalic acid) can be used as a catalyst for the reaction.
- acids containing no impurity elements specifically, hydrochloric acid, sulfuric acid, p. -Toluenesulfonic acid or oxalic acid
- a conventionally well-known method can also be adopted for the production of the novolac type phenol resin. That is, 0.5 to 0.9 mole of aldehyde and 0.02 to 0.2 mole of an inorganic or organic acid not containing an impurity element are added to 1 mole of phenol and heated to 60 to 100 ° C. .
- liquid aluminum alkoxide As an aluminum-containing raw material (hereinafter, appropriately referred to as an aluminum source) containing a hydrolyzable aluminum compound, for example, liquid aluminum alkoxide is used. Specific examples of the liquid aluminum alkoxide include aluminum diisopropylate monosecondary butyrate (Al (O—iC 3 H 7 ) 2 (o-secC 4 H 9 )).
- the composite powder generation step S102 is a step of generating composite powder. Specifically, the composite precursor is heated and fired in an inert atmosphere containing nitrogen to generate a composite powder containing silicon carbide and aluminum nitride.
- the heating temperature is preferably about 1500 to 2000 ° C.
- the firing time is preferably about 30 minutes to 10 hours.
- nitrogen may be used, or an inert gas containing nitrogen may be used.
- the inert gas include vacuum, helium, and argon.
- the silicon carbide precursor contained in the composite precursor is carbonized and silicified, and the aluminum nitride precursor contained in the composite precursor is carbonized and nitride-reduced.
- silicon contained in the silicon carbide precursor becomes a reducing agent and the following reaction occurs by heating and firing.
- the compounding ratio of silicon element and carbon element and the compounding ratio of aluminum element and carbon element can be determined. That is, the Si / C ratio is 1, and the Al / C ratio is 0.67.
- Each raw material is adjusted based on this ratio. Specifically, the silicon-containing raw material, the carbon-containing raw material, and the weight ratio of silicon carbide to aluminum nitride (silicon carbide / aluminum nitride) contained in the composite powder are in the range of 25/75 to 75/25. The amount of the aluminum-containing raw material is adjusted.
- the above reaction produces a fine composite powder in which silicon carbide powder and aluminum nitride powder are mixed.
- a so-called decarburization treatment in which the composite powder is heated and fired at a temperature of 700 ° C., for example, may be performed using an atmospheric furnace.
- the composite powder may be pulverized using, for example, a jet mill so that the center particle size becomes 1 to 2 ⁇ m.
- the mixing step S103 is a step of adding and mixing a sintering aid to the composite powder. It is preferable to mix a phenol resin as a sintering aid for the silicon carbide powder and yttrium oxide (Y 2 O 3 ) as a sintering aid for the aluminum nitride powder.
- a phenol resin as a sintering aid for the silicon carbide powder
- Y 2 O 3 yttrium oxide
- the phenol resin which is a non-metallic sintering aid can be used by dissolving in an organic solvent.
- the organic solvent lower alcohols such as ethyl alcohol and acetone can be selected.
- the sintering aid is well mixed with the composite powder, water, lower alcohols such as ethyl alcohol, ethyl ether, acetone and the like can be used as a solvent. It is preferable to use a solvent having a low impurity content. An antifoaming agent such as silicone can also be added.
- a solvent is used, a slurry-like mixture is obtained. The obtained slurry-like mixture is dried using, for example, a hot plate. Thereby, a composite powder containing a sintering aid is obtained. If necessary, the composite powder is sieved.
- Sintering step S104 is a step of sintering the composite powder. Specifically, the composite powder is put in a mold and hot press sintered. The mold is pressed and heated at a surface pressure of 150 kg / cm 2 to 350 kg / cm 2 . The heating temperature is preferably 1700 ° C. to 2200 ° C. The inside of the heating furnace is an inert atmosphere.
- the ceramic sintered body according to the present embodiment can be manufactured.
- the ceramic sintered body according to the present embodiment includes only a composite of silicon carbide and aluminum nitride and a sintering aid, excluding impurities.
- a silicon-containing raw material, a carbon-containing raw material, an aluminum-containing raw material, and water are mixed to produce a composite precursor.
- the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the powder is greater than 10% and not greater than 97%.
- the ceramic sintered body according to the present embodiment is produced by a general manufacturing method.
- the density is higher than that of a ceramic sintered body produced by mixing the silicon carbide powder and aluminum nitride.
- the ceramic sintered body according to the present embodiment has a bulk density greater than 3.18 g / cm 3 .
- silicon carbide is solid-phase sintered, a plurality of pores are generally formed in the silicon carbide ceramic sintered body.
- a mixed powder in which silicon carbide powder and aluminum nitride powder are mixed is sintered. Since aluminum nitride undergoes liquid phase sintering, material diffusion proceeds, so that it is difficult to form pores. For this reason, in the ceramic sintered body of the present embodiment, the number of holes is reduced and the size of the holes is also reduced. For this reason, it becomes a dense ceramic sintered body and has high strength.
- the composite powder produced from the composite precursor is composed of silicon carbide and aluminum nitride at the molecular level. Good dispersion. For this reason, it becomes difficult to form a void
- the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the composite powder is greater than 11% and not more than 90%, or the weight ratio of silicon carbide and aluminum nitride is By sintering composite powder in the range of 25/75 or more and 75/25 or less, the balance between the amount of silicon carbide and the amount of aluminum nitride is good, and silicon carbide and aluminum nitride are easily dissolved. Become. Furthermore, since silicon carbide and aluminum nitride are well dispersed at the molecular level, silicon carbide and aluminum nitride are easily dissolved. It is considered that the crystal structure of silicon carbide was changed by the solid solution, and as a result, the thermal conductivity of the ceramic sintered body was lowered.
- the method further includes a step of mixing the composite powder with a phenol resin and yttrium oxide.
- Phenol resin serves as a sintering aid for silicon carbide powder
- yttrium oxide serves as a sintering aid for aluminum nitride powder.
- a ceramic sintered body having a thermal conductivity of 30 W / mK or less can be obtained. This can be suitably used as a heat insulating material requiring strength.
- the ceramic sintered body of the present embodiment is not limited to the members constituting the semiconductor device, and can be used in various fields.
- Ceramic sintered bodies according to Examples and Comparative Examples were manufactured using the following methods. Specifically, in Examples 1 to 6 and Comparative Examples 1 and 2, the method for manufacturing a ceramic sintered body according to the first embodiment was used. In Examples 7 to 12 and Comparative Examples 3 and 4, the method for manufacturing a ceramic sintered body according to the second embodiment was used.
- a silicon carbide precursor was produced using ethyl silicate as the silicon-containing raw material and phenol resin as the silicon carbide raw material.
- ethyl silicate as the silicon-containing raw material
- phenol resin as the silicon carbide raw material.
- 212 g of ethyl silicate and 94.5 g of phenol resin were mixed.
- 31.6 g of aqueous maleic acid solution (70% concentration) was added as a catalyst to the mixture.
- the mixture was stirred and mixed for 30 minutes to obtain a viscous product.
- the viscous product was dried on a hot plate at 110 ° C. This produced a silicon carbide precursor.
- the produced silicon carbide precursor was heated and fired at 1900 ° C. for 6 hours in an argon atmosphere. Thereby, silicon carbide powder was produced.
- the produced silicon carbide powder was placed in an atmospheric furnace and heated at 700 ° C. Using a jet mill, the heated silicon carbide powder was pulverized so as to have a center particle diameter of 1 to 2 ⁇ m.
- An aluminum nitride precursor was produced using an aluminum nitride raw material as the aluminum diisopropylate monosecondary butyrate (Al (O-iC 3 H 7 ) 2 (o-secC 4 H 9 ): AMD) and a silicon carbide raw material as the phenol resin. .
- AMD 239.5g and phenol resin 39.5g were mixed.
- 88 g of aqueous maleic acid solution (70% concentration) was added as a catalyst to the mixture.
- the mixture became a fine viscous product as the hydrolysis reaction proceeded.
- the fine viscous product was dried on a hot plate at 110 ° C. This produced an aluminum nitride precursor.
- the produced aluminum nitride precursor was heated and fired in a nitrogen atmosphere at 1900 ° C. for 6 hours. This produced aluminum nitride powder.
- the produced aluminum nitride powder was placed in an atmospheric furnace and heated at 700 ° C. Using a jet mill, the heated silicon carbide powder was pulverized so as to have a center particle diameter of 1 to 2 ⁇ m.
- Example 1 a slurry mixture was prepared so that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 10.6%. Specifically, 80.6 g of silicon carbide powder, 9.4 g of aluminum nitride powder, and 100 g of ethanol were mixed using a ball mill. This created a slurry mixture. The silicon carbide powder contains 9.5 g of phenol resin, and the aluminum nitride powder contains 0.4 g of yttrium oxide.
- the slurry-like mixture was dried on a 110 ° C. hot plate.
- the composite powder obtained by drying was passed through a 200 ⁇ m sieve. As a result, a composite powder having a size of less than 200 ⁇ m was obtained.
- 9 g of the obtained composite powder was filled in a graphite mold having a diameter of 30 mm.
- the graphite mold was put into a heating furnace, and hot press sintered under conditions of 2100 ° C., 3 hours, 300 kg / cm 2 and argon atmosphere. Thereby, the ceramic sintered body of Example 1 was obtained.
- Example 2 a slurry-like mixture was prepared such that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 26.3%. Specifically, 67.1 g of silicon carbide powder, 24.0 g of aluminum nitride powder, and 100 g of ethanol were mixed using a ball mill. A ceramic sintered body of Example 2 was obtained by the same operation as in Example 1 except for the weight ratio. The silicon carbide powder contains 7.9 g of phenol resin, and the aluminum nitride powder contains 1.0 g of yttrium oxide.
- Example 3 a slurry mixture was prepared so that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 51.8%. Specifically, 44.8 g of silicon carbide powder, 48.0 g of aluminum nitride powder, and 100 g of ethanol were mixed using a ball mill. A ceramic sintered body of Example 3 was obtained by the same operation as Example 1 except for the weight ratio. The silicon carbide powder contains 5.3 g of phenol resin, and the aluminum nitride powder contains 2.0 g of yttrium oxide.
- Example 4 a slurry-like mixture was prepared such that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 76.3%. Specifically, 22.4 g of silicon carbide powder, 72.0 g of aluminum nitride powder, and 100 g of ethanol were mixed using a ball mill. A ceramic sintered body of Example 4 was obtained by the same operation as Example 1 except for the weight ratio. The silicon carbide powder contains 2.6 g of phenol resin, and the aluminum nitride powder contains 3.0 g of yttrium oxide.
- Example 5 a slurry-like mixture was prepared such that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 90.6%. Specifically, 9.0 g of silicon carbide powder, 86.4 g of aluminum nitride powder, and 100 g of ethanol were mixed using a ball mill. A ceramic sintered body of Example 5 was obtained by the same operation as in Example 1 except for the weight ratio.
- the silicon carbide powder includes 1.1 g of phenol resin, and the aluminum nitride powder includes 3.6 g of yttrium oxide.
- Example 6 a slurry-like mixture was prepared such that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 95.3%. Specifically, 4.5 g of silicon carbide powder, 91.2 g of aluminum nitride powder, and 100 g of ethanol were mixed using a ball mill. A ceramic sintered body of Example 6 was obtained in the same manner as in Example 1 except for the weight ratio. The silicon carbide powder contains 0.5 g of phenol resin, and the aluminum nitride powder contains 3.8 g of yttrium oxide.
- Example 7 to 12 The silicon-containing raw material is ethyl silicate, the silicon carbide raw material is phenol resin, and the aluminum-containing raw material is aluminum diisopropylate monosecondary butyrate (Al (O-iC 3 H 7 ) 2 (o-secC 4 H 9 ): AMD), A composite precursor was produced.
- the ceramic sintered body of Example 7 was manufactured by the following manufacturing method so that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 10.6%. Manufactured.
- the produced composite precursor was heated and fired at 1900 ° C. in an argon atmosphere containing nitrogen. This produced composite powder.
- the produced composite powder was placed in an atmospheric furnace and heated at 700 ° C. Using a jet mill, the heated composite powder was pulverized so as to have a center particle size of 1 to 2 ⁇ m.
- Example 8 the ceramic sintered body was manufactured such that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 26.3%. Specifically, 212 g of ethyl silicate and 94.5 g of phenol resin were mixed. 31.6 g of aqueous maleic acid solution (70% concentration) was added as a catalyst to the mixture. The mixture was stirred and mixed for 30 minutes to obtain a viscous product. Next, AMD 79.9g and phenol resin 13.1g were mixed with the viscous thing. 29.4 g of aqueous maleic acid solution (70% concentration) was added as a catalyst to the mixture. Otherwise, a composite powder was produced in the same manner as in Example 1.
- Example 9 the ceramic sintered body was manufactured such that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 51.8%. Specifically, 141.3 g of ethyl silicate and 63 g of phenol resin were mixed. 21.1 g of aqueous maleic acid solution (70% concentration) was added as a catalyst to the mixture. The mixture was stirred and mixed for 30 minutes to obtain a viscous product. Next, AMD159.8g and phenol resin 26.2g were mixed with the viscous thing. To the mixture, 58.8 g of an aqueous maleic acid solution (70% concentration) was added as a catalyst.
- Example 7 a composite powder was produced in the same manner as in Example 1. 100 g of the produced composite powder, 5.3 g of phenol resin, 2.0 g of yttrium oxide, and 100 g of ethanol were mixed using a ball mill to prepare a slurry mixture. Otherwise, a ceramic sintered body was produced in the same manner as in Example 7.
- Example 10 the ceramic sintered body was manufactured such that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 76.3%. Specifically, 70.7 g of ethyl silicate and 31.5 g of phenol resin were mixed. 10.5 g of aqueous maleic acid solution (70% concentration) was added as a catalyst to the mixture. The mixture was stirred and mixed for 30 minutes to obtain a viscous product. Next, AMD 239.7g and phenol resin 39.3g were mixed with the viscous thing. 88.2 g of aqueous maleic acid solution (70% concentration) was added as a catalyst to the mixture.
- Example 7 a composite powder was produced in the same manner as in Example 1. 100 g of the produced composite powder, 2.6 g of phenol resin, 3.0 g of yttrium oxide, and 100 g of ethanol were mixed using a ball mill to prepare a slurry mixture. Otherwise, a ceramic sintered body was produced in the same manner as in Example 7.
- Example 11 the ceramic sintered body was manufactured such that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 90.6%. Specifically, 28.3 g of ethyl silicate and 12.6 g of phenol resin were mixed. To the mixture, 4.2 g of an aqueous maleic acid solution (70% concentration) was added as a catalyst. The mixture was stirred and mixed for 30 minutes to obtain a viscous product. Next, AMD287.6g and phenol resin 47.2g were mixed with the viscous thing. 105.8 g of aqueous maleic acid solution (70% concentration) was added as a catalyst to the mixture.
- Example 7 a composite powder was produced in the same manner as in Example 1. 100 g of the produced composite powder, 1.1 g of phenol resin, 3.6 g of yttrium oxide, and 100 g of ethanol were mixed using a ball mill to prepare a slurry mixture. Otherwise, a ceramic sintered body was produced in the same manner as in Example 7.
- Example 12 the ceramic sintered body was manufactured such that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 95.3%. Specifically, 14.1 g of ethyl silicate and 6.3 g of phenol resin were mixed. To the mixture, 2.1 g of an aqueous maleic acid solution (70% concentration) was added as a catalyst. The mixture was stirred and mixed for 30 minutes to obtain a viscous product. Next, AMD303.6g and phenol resin 49.8g were mixed with the viscous thing. To the mixture, 111.7 g of an aqueous maleic acid solution (70% concentration) was added as a catalyst.
- Example 7 a composite powder was produced in the same manner as in Example 1. 100 g of the produced composite powder, 0.5 g of phenol resin, 3.8 g of yttrium oxide, and 100 g of ethanol were mixed using a ball mill to prepare a slurry mixture. Otherwise, a ceramic sintered body was produced in the same manner as in Example 7.
- Comparative Example 1 a slurry mixture was prepared so that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 3.2%. Specifically, 86.8 g of silicon carbide powder, 2.9 g of aluminum nitride powder, and 100 g of ethanol were mixed using a ball mill. A ceramic sintered body of Comparative Example 1 was obtained by the same operation as in Example 1 except for the weight ratio. The silicon carbide powder contains 10.2 g of phenol resin, and the aluminum nitride powder contains 0.1 g of yttrium oxide.
- Comparative Example 2 a slurry mixture was prepared such that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 97.2%. Specifically, 2.7 g of silicon carbide powder, 93.1 g of aluminum nitride powder, and 100 g of ethanol were mixed using a ball mill. A ceramic sintered body of Comparative Example 2 was obtained by the same operation as in Example 1 except for the weight ratio. The silicon carbide powder contains 0.3 g of phenol resin, and the aluminum nitride powder contains 3.9 g of yttrium oxide.
- a ceramic sintered body was manufactured such that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 3.2%. Specifically, 274.2 g of ethyl silicate and 122.2 g of phenol resin were mixed. 40.8 g of aqueous maleic acid solution (70% concentration) was added as a catalyst to the mixture. The mixture was stirred and mixed for 30 minutes to obtain a viscous product. Next, AMD 9.6g and the phenol resin 1.6g were mixed with the viscous thing. To the mixture, 3.5 g of an aqueous maleic acid solution (70% concentration) was added as a catalyst.
- Example 7 a composite powder was produced in the same manner as in Example 1. 100 g of the produced composite powder, 10.2 g of phenol resin, 0.1 g of yttrium oxide, and 100 g of ethanol were mixed using a ball mill to prepare a slurry mixture. Otherwise, a ceramic sintered body was produced in the same manner as in Example 7.
- a ceramic sintered body was manufactured such that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 97.2%. Specifically, 8.5 g of ethyl silicate and 3.8 g of phenol resin were mixed. 1.3 g of aqueous maleic acid solution (70% concentration) was added as a catalyst to the mixture. The mixture was stirred and mixed for 30 minutes to obtain a viscous product. Next, AMD 310.0g and phenol resin 50.8g were mixed with the viscous thing. To the mixture, 114.1 g of an aqueous maleic acid solution (70% concentration) was added as a catalyst.
- Example 7 a composite powder was produced in the same manner as in Example 1. 100 g of the produced composite powder, 0.3 g of phenol resin, 3.9 g of yttrium oxide, and 100 g of ethanol were mixed using a ball mill to prepare a slurry mixture. Otherwise, a ceramic sintered body was produced in the same manner as in Example 7.
- Comparative Examples 5 to 7 commercially available silicon carbide powder (manufactured by Bridgestone) and aluminum nitride powder (manufactured by Tokuyama: AlN-E powder) were used. That is, Comparative Examples 5 to 7 used silicon carbide powder and aluminum nitride powder produced without using a silicon carbide precursor and an aluminum nitride precursor.
- Comparative Example 5 a slurry-like mixture was prepared such that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 1.1%.
- a ceramic sintered body of Comparative Example 5 was obtained in the same manner as in Example 1 except for the silicon carbide powder and the aluminum nitride powder and the weight ratio.
- Comparative Example 6 a slurry mixture was prepared so that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 10.6%.
- a ceramic sintered body of Comparative Example 6 was obtained by the same operation as Example 1 except for the silicon carbide powder and the aluminum nitride powder and the weight ratio.
- Comparative Example 7 a slurry-like mixture was prepared such that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body was 31.5%.
- a ceramic sintered body of Comparative Example 7 was obtained in the same manner as in Example 1 except for the silicon carbide powder and aluminum nitride powder and the weight ratio.
- FIG. 4 is a graph of bulk density according to Examples and Comparative Examples.
- FIG. 5 is a graph of thermal conductivity according to examples and comparative examples.
- FIG. 6 is a graph of bending strength according to the example and the comparative example.
- FIG. 7 is a graph of plasma resistance according to examples and comparative examples.
- Examples 1 to 6 manufactured using the manufacturing method according to the first embodiment are indicated by “ ⁇ ”.
- Examples 7 to 12 manufactured by using the manufacturing method according to the second embodiment are indicated by “ ⁇ ”.
- Comparative Examples 1 and 2 manufactured using the manufacturing method according to the first embodiment are indicated by “ ⁇ ”.
- Comparative Examples 3 and 4 manufactured using the manufacturing method according to the second embodiment are indicated by “ ⁇ ”.
- Comparative Examples 5 to 7 are indicated by “ ⁇ ”.
- the bulk density was calculated from the porosity using the Archimedes method. The results are shown in Table 1 and FIG.
- the thermal conductivity was measured using each ceramic sintered body processed to ⁇ 10 mm ⁇ t1 mm. The results are shown in Table 1 and FIG.
- each ceramic sintered body was processed to 4 mm ⁇ 3 mm ⁇ 26 mm and polished.
- a ceramic sintered body that was a rectangular parallelepiped having a length of 4 mm, a width of 3 mm, and a height of 26 mm was prepared.
- the crosshead speed was 5 mm / min, the distance between spans was 20 mm, and the bending strength was measured under the three-point bending conditions.
- each ceramic sintered body was supported at two points separated by 20 mm. Pressure was applied from the pressing surface, which is the surface opposite to the supporting surface of each ceramic sintered body in contact with the two points to be supported. The point where the pressure was applied was positioned at the center of the two points so that the load was evenly distributed at the two points. The results are shown in Table 1 and FIG.
- the results are shown in Table 1 and FIG.
- the ceramic sintered bodies of Examples 1 to 12 had a bulk density higher than 3.18 g / cm 3 .
- the ceramic sintered bodies of Comparative Examples 1 and 5 to 7 had a bulk density of 3.18 g / cm 3 or less. Therefore, it is found that the ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) larger than 10% and 97% or less has a bulk density larger than 3.18 g / cm 3. It was. It was found that a ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) of 10.6% or less and 95.3% or less has a bulk density greater than 3.18 g / cm 3. It was.
- the ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) larger than 52% and 97% or less has a bulk density larger than 3.23 g / cm 3. It was. It was found that a ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) larger than 76% and smaller than 96% had a bulk density larger than 3.23 g / cm 3 .
- the ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) of 76.3% or more and 95.3% or less may have a bulk density larger than 3.23 g / cm 3. I understood.
- the ceramic sintered bodies of Examples 1 to 12 had a thermal conductivity of 65 W / mK or less.
- the ceramic sintered bodies of Comparative Examples 1 and 5 to 7 had a thermal conductivity higher than 65 W / mK. Therefore, it was found that the ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) larger than 10% and 97% or less has a thermal conductivity of 65 W / mK or less. . It was found that a ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) of 10.6% or less and 95.3% or less has a thermal conductivity of 65 W / mK or less. .
- the ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) of 11% or more and 90% or less has a thermal conductivity of 40 W / mK or less. It was found that a ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) larger than 26% and smaller than 77% has a thermal conductivity of 40 W / mK or less.
- a ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) of 26.3% or more and 76.3% or less is found to have a thermal conductivity of 40 W / mK or less. It was.
- the ceramic sintered bodies of Examples 1 to 3 and 7 to 9 had a bending strength of 700 MPa or more. Therefore, it was found that the ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) larger than 10% and 76% or less has a bending strength of 700 MPa or more. It was found that the ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) larger than 10% and smaller than 52% has a bending strength of 700 MPa or more. It was found that the ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) of 10.6% or more and 51.8% or less has a bending strength of 700 MPa or more.
- the ceramic sintered bodies of Examples 3 to 6 and 9 to 12 had a wear amount of 20 ⁇ g / cm 2 or less. Therefore, it was found that the ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) of 27% or more and 97% or less has a wear amount of 20 ⁇ g / cm 2 or less. It was found that the ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) larger than 51% and smaller than 96% has a wear amount of 20 ⁇ g / cm 2 or less. It was found that the ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) of 51.8% or more and 95.3% or less has a wear amount of 20 ⁇ g / cm 2 or less. It was.
- the amount of wear of the ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) of 52% or more and 97% or less is less than 10 ⁇ g / cm 2 . It was found that a ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) larger than 76% and smaller than 96% has a wear amount of less than 10 ⁇ g / cm 2 . It was found that the ceramic sintered body having (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) of 76.3% or more and 95.3% or less has a wear amount of less than 10 ⁇ g / cm 2. It was.
- the ceramic sintered body according to the present invention has a large bulk density and good heat insulation.
- the ceramic sintered bodies of Examples 1 to 3 manufactured using the manufacturing method according to the first embodiment have a bending strength of 800 MPa or more and a plasma resistance of 100 ⁇ g / cm 2. Was less than. Therefore, the ceramics of Examples 1 to 3 manufactured using the manufacturing method according to the first embodiment, and (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) is larger than 10% and smaller than 76%. It was found that the sintered body has high strength and good plasma resistance.
- the ceramic sintered bodies of Examples 1 and 2 in which (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) is larger than 10% and smaller than 51% have a bending strength of 900 MPa or more and strength. It turned out to be excellent.
- the ceramic sintered bodies of Examples 9 to 11 manufactured using the manufacturing method according to the second embodiment have a bending strength of 400 MPa or more and a thermal conductivity of 10 W / mK. It was the following. Therefore, the ceramics of Examples 9 to 11 manufactured using the manufacturing method according to the first embodiment, wherein (AlN weight ratio) / (SiC weight ratio + AlN weight ratio) is larger than 27% and smaller than 94%. It was found that the sintered body had high strength and good heat insulation.
- FIG. 8 shows the results of XRD diffraction of Example 9 and Comparative Examples 8 and 9.
- Comparative Example 8 a ceramic sintered body using only silicon carbide powder so that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body is 0%. It was created.
- silicon carbide powder obtained from a silicon carbide precursor produced by mixing a silicon source and a carbon source was used. Specifically, ethyl silicate, phenol resin, and maleic acid aqueous solution were mixed to produce a silicon carbide precursor. The produced silicon carbide precursor was heated and fired in an argon atmosphere to obtain silicon carbide powder. A phenol resin and ethanol were added to the resulting silicon carbide powder, and a slurry mixture was prepared using a ball mill. A ceramic sintered body was obtained in the same manner as in Example 1 using the mixed powder obtained from the slurry mixture.
- Comparative Example 9 a ceramic sintered body using only aluminum nitride powder so that the weight ratio of aluminum nitride to the total weight ratio of silicon carbide and aluminum nitride contained in the ceramic sintered body is 100%. It was created.
- a silicon carbide powder obtained from an aluminum nitride precursor produced by mixing an aluminum nitride source and a carbon source was used. Specifically, AMD, a phenol resin, and an aqueous maleic acid solution were mixed to produce an aluminum nitride precursor. The produced aluminum nitride precursor was heated and fired in a nitrogen atmosphere to obtain an aluminum nitride powder.
- Yttrium oxide and ethanol were added to the obtained aluminum nitride powder, and a slurry-like mixture was prepared using a ball mill.
- a ceramic sintered body was obtained in the same manner as in Example 1 using the mixed powder obtained from the slurry mixture.
- Example 9 In Comparative Example 8 (silicon carbide powder only), a 3C—SiC peak was observed, and in Comparative Example 9 (aluminum nitride powder only), an AlN peak was observed. On the other hand, in Example 9 produced from silicon carbide powder and aluminum nitride powder, a 2H—SiC peak was observed. This indicates that silicon carbide and aluminum nitride are in solid solution. When silicon carbide and aluminum nitride are dissolved, the crystal structure of silicon carbide is changed. In Example 9, it is considered that the thermal conductivity is lowered. Similarly, in other examples, it is considered that the crystal structure of silicon carbide is changed due to the solid solution of silicon carbide and aluminum nitride, and the thermal conductivity is lowered.
- the present invention it is possible to provide a composite ceramic sintered body of silicon carbide and aluminum nitride having a large bulk density and good heat insulation, and a method for producing the ceramic sintered body.
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Abstract
Description
本実施形態に係るセラミックス焼結体について、説明する。
従来、炭化ケイ素と窒化アルミニウムとの複合セラミックス焼結体は、高強度、耐熱性などの優れた特性を有するため、半導体ウエハの製造装置を構成する部材として用いられてきた。
原料生成工程S1は、炭化ケイ素原料及び窒化アルミニウム原料を生成する工程である。
炭化ケイ素原料は、炭化ケイ素前駆体生成工程S11aと炭化ケイ素原料生成工程S12aとによって、生成される。
炭化ケイ素前駆体生成工程S11aは、炭化ケイ素前駆体を生成する工程である。まず、液状のケイ素化合物を含有するケイ素含有原料と、加熱により炭素を生成する有機化合物を含有する炭素含有原料とを準備する。
液状のケイ素化合物を含有するケイ素含有原料(以下、適宜、ケイ素源と称する)としては、以下に示す液状のケイ素化合物が用いられる。液状のケイ素化合物だけでなく、固体状のケイ素化合物を併用したケイ素源を準備してもよい。
加熱により炭素を生成する有機化合物を含有する炭素含有原料(以下、適宜、炭素源と称する)としては、以下に示す有機化合物が用いられる。炭素含有原料として、不純物元素を含まない触媒を用いて合成され、加熱及び/又は触媒、若しくは架橋剤により重合又は架橋して硬化しうる任意の1種もしくは2種以上の有機化合物から構成されるモノマー、オリゴマー及びポリマーが好ましい。
炭化ケイ素原料生成工程S12aは、炭化ケイ素前駆体を不活性雰囲気化で加熱焼成し、炭化ケイ素原料を生成する工程である。具体的には、炭化ケイ素前駆体を不活性気体の雰囲気下で加熱焼成して、炭化ケイ素前駆体を炭化及び珪化する。不活性気体としては、例えば、真空、窒素、ヘリウムまたはアルゴンが挙げられる。
SiO2+C → SiC
窒化アルミニウム原料は、窒化アルミニウム前駆体生成工程S11bと窒化アルミニウム原料生成工程S12bとによって、生成される。
窒化アルミニウム前駆体生成工程S11bは、窒化アルミニウム前駆体を生成する工程である。まず、加水分解型のアルミニウム化合物を含有するアルミニウム含有原料と、加熱により炭素を生成する有機化合物を含有する炭素含有原料とを準備する。
窒化アルミニウム原料生成工程S12bは、窒素雰囲気下において窒化アルミニウム前駆体を加熱焼成し、窒化アルミニウム原料を生成する工程である。窒素雰囲気下において窒化アルミニウム前駆体を加熱焼成することによって、窒化アルミニウム前駆体を炭化処理及び窒化還元処理する。加熱焼成によって、窒化アルミニウム前駆体は、酸化アルミニウムを経て、以下の反応式により、窒化アルミニウムを生じる。
Al2O3+3C+N2 → 2AlN+3CO
混合工程S2は、炭化ケイ素原料と窒化アルミニウム原料とを混合する工程である。上述の工程S1により得られた炭化ケイ素粉体と窒化アルミニウム粉体とを混合し、スラリー状の混合物を得る。
焼結工程S3は、炭化ケイ素原料と窒化アルミニウム原料との混合物を焼結する工程である。具体的には、炭化ケイ素粉体と窒化アルミニウム粉体との混合粉体をモールドに入れ、ホットプレス焼結する。モールドを面圧150kg/cm2~350kg/cm2で型押しするとともに加熱する。加熱温度は、1700℃~2200℃とすることが好ましい。加熱炉内は、不活性雰囲気にする。
以上説明した本実施形態に係るセラミックス焼結体の製造方法によれば、ケイ素源と炭素源とを混合し、炭化ケイ素前駆体を生成する炭化ケイ素前駆体生成工程S11aと、不活性雰囲気下において炭化ケイ素前駆体を加熱焼成し、炭化ケイ素粉体を生成する炭化ケイ素原料生成工程S12aと、アルミニウム源と炭素源と水とを混合し、窒化アルミニウム前駆体を生成する窒化アルミニウム前駆体生成工程S11bと、窒素雰囲気下において窒化アルミニウム前駆体を加熱焼成し、窒化アルミニウム粉体を生成する工程S12bと、炭化ケイ素粉体と窒化アルミニウム粉体とを混合する混合工程S2と、炭化ケイ素粉体と窒化アルミニウム粉体との混合粉体を焼結する焼結工程S3と、を備える。また、炭化ケイ素原料と窒化アルミニウム原料との混合物に含まれる炭化ケイ素と窒化アルミニウムとの合計の重量比に対する窒化アルミニウムの重量比は、10%より大きく、かつ、97%以下である。
従来、強度の高い材料として、炭化ケイ素と窒化アルミニウムとの複合セラミックス焼結体が知られている。このようなセラミックス焼結体は、強度が高いため、例えば、半導体の製造装置を構成する部材として用いられる。
複合前駆体生成工程S101は、複合前駆体を生成する工程である。具体的には、ケイ素含有原料と、炭素含有原料と、アルミニウム含有原料と、水とを混合し、複合前駆体を生成する。
液状のケイ素化合物を含有するケイ素含有原料(以下、適宜、ケイ素源と称する)としては、以下に示す液状のケイ素化合物が用いられる。液状のケイ素化合物だけでなく、固体状のケイ素化合物を併用したケイ素源を準備してもよい。
加熱により炭素を生成する有機化合物を含有する炭素含有原料(以下、適宜、炭素源と称する)としては、以下に示す有機化合物が用いられる。炭素含有原料として、不純物元素を含まない触媒を用いて合成され、加熱及び/又は触媒、若しくは架橋剤により重合又は架橋して硬化しうる任意の1種もしくは2種以上の有機化合物から構成されるモノマー、オリゴマー及びポリマーが好ましい。
加水分解型のアルミニウム化合物を含有するアルミニウム含有原料(以下、適宜、アルミニウム源と称する)としては、例えば、液状のアルミニウムアルコキシドが用いられる。具体的には、液状のアルミニウムアルコキシドとして、アルミニウムジイソプロピレートモノセカンダリブチレート(Al(O-iC3H7)2(o-secC4H9))が挙げられる。
複合粉体生成工程S102は、複合粉体を生成する工程である。具体的には、窒素を含む不活性雰囲気下において複合前駆体を加熱焼成し、炭化ケイ素及び窒化アルミニウムを含有する複合粉体を生成する。
SiO2+C → SiC
Al2O3+3C+N2 → 2AlN+3CO
混合工程S103は、複合粉体に焼結助剤を加えて混合する工程である。炭化ケイ素粉体の焼結助剤として、フェノール樹脂を混合し、窒化アルミニウム粉体の焼結助剤として、酸化イットリウム(Y2O3)を混合することが好ましい。フェノール樹脂としては、レゾール型フェノール樹脂が好ましい。非金属系焼結助剤であるフェノール樹脂は、有機溶媒に溶解して用いることもできる。有機溶媒としては、エチルアルコール等の低級アルコール類、アセトンを選択することができる。
焼結工程S104は、複合粉体を焼結する工程である。具体的には、複合粉体をモールドに入れ、ホットプレス焼結する。モールドを面圧150kg/cm2~350kg/cm2で型押しするとともに加熱する。加熱温度は、1700℃~2200℃とすることが好ましい。加熱炉内は、不活性雰囲気にする。
以上説明した本実施形態に係るセラミックス焼結体の製造方法によれば、ケイ素含有原料と炭素含有原料とアルミニウム含有原料と水とを混合し、複合前駆体を生成する工程と、窒素を含む不活性雰囲気下において複合前駆体を加熱焼成し、炭化ケイ素及び窒化アルミニウムを含有する複合粉体を生成する工程と、複合粉体を焼結する工程と、を備え、複合粉体に含まれる炭化ケイ素と窒化アルミニウムとの合計の重量比に対する窒化アルミニウムの重量比は、10%より大きく、かつ、97%以下である。
本発明の効果を確かめるために、以下の比較評価を行った。なお、本発明は、以下の実施例に限定されない。
以下の方法を用いて、実施例及び比較例に係るセラミックス焼結体を製造した。具体的には、実施例1~6、比較例1,2は、第1実施形態に係るセラミックス焼結体の製造方法を用いた。実施例7~12、比較例3,4は、第2実施形態に係るセラミックス焼結体の製造方法を用いた。
ケイ素含有原料をエチルシリケート、炭化ケイ素原料をフェノール樹脂として、炭化ケイ素前駆体を生成した。まず、エチルシリケート212g、フェノール樹脂94.5gを混合した。混合物に触媒としてマレイン酸水溶液(70%濃度)31.6gを添加した。混合物を30分間攪拌混合して、粘調物を得た。110℃のホットプレート上で、粘調物を乾燥させた。これにより、炭化ケイ素前駆体を生成した。
ケイ素含有原料をエチルシリケート、炭化ケイ素原料をフェノール樹脂、アルミニウム含有原料をアルミニウムジイソプロピレートモノセカンダリブチレート(Al(O-iC3H7)2(o-secC4H9):AMD)として、複合前駆体を生成した。実施例7のセラミックス焼結体は、セラミックス焼結体に含まれる炭化ケイ素と窒化アルミニウムとの合計の重量比に対する窒化アルミニウムの重量比が、10.6%となるように、以下の製造方法により、製造した。
比較例1では、セラミックス焼結体に含まれる炭化ケイ素と窒化アルミニウムとの合計の重量比に対する窒化アルミニウムの重量比が、3.2%となるように、スラリー状混合物を作成した。具体的には、炭化ケイ素粉体86.8g、窒化アルミニウム粉体2.9g、エタノール100gをボールミルを用いて、混合した。重量比を除いて、実施例1と同様の操作により、比較例1のセラミックス焼結体を得た。なお、炭化ケイ素粉体には、フェノール樹脂10.2gが含まれており、窒化アルミニウム粉体には、酸化イットリウム0.1gが含まれている。
上述の方法により製造されたセラミックス焼結体を用いて、嵩密度、熱伝導率、曲げ強度、プラズマ耐性を測定した。結果を表1及び図4~図7に示す。図4は、実施例及び比較例に係る嵩密度のグラフである。図5は、実施例及び比較例に係る熱伝導率のグラフである。図6は、実施例及び比較例に係る曲げ強度のグラフである。図7は、実施例及び比較例に係るプラズマ耐性のグラフである。
表1及び図4に示されるように、実施例1~12のセラミックス焼結体は、嵩密度が3.18g/cm3より大きかった。比較例1、5~7のセラミックス焼結体は、嵩密度が3.18g/cm3以下であった。従って、(AlN重量比)/(SiC重量比+AlN重量比)が、10%より大きく、かつ、97%以下であるセラミックス焼結体は、嵩密度が3.18g/cm3より大きいことが分かった。(AlN重量比)/(SiC重量比+AlN重量比)が、10.6%以下、かつ95.3%以下であるセラミックス焼結体は、嵩密度が3.18g/cm3より大きいことが分かった。
図8には、実施例9、比較例8,9のXRD回折の結果が示されている。
Claims (21)
- 炭化ケイ素と窒化アルミニウムとを含み、
前記炭化ケイ素と前記窒化アルミニウムとの合計の重量比に対する前記窒化アルミニウムの重量比は、10%より大きく、かつ、97%以下であり、
嵩密度が3.18g/cm3より大きいセラミックス焼結体。 - 熱伝導率が65W/mK以下である請求項1に記載のセラミックス焼結体。
- 熱伝導率が40W/mK以下である請求項2に記載のセラミックス焼結体。
- 前記炭化ケイ素と前記窒化アルミニウムとの合計の重量比に対する前記窒化アルミニウムの重量比は、11%以上、かつ、90%以下である請求項1~3の何れか1項に記載のセラミックス焼結体。
- 嵩密度が3.23g/cm3以上である請求項1~4の何れか1項に記載のセラミックス焼結体。
- 前記炭化ケイ素と前記窒化アルミニウムとの合計の重量比に対する前記窒化アルミニウムの重量比は、52%以上、かつ、97%以下である請求項1~5の何れか1項に記載のセラミックス焼結体。
- 前記炭化ケイ素と前記窒化アルミニウムとの合計の重量比に対する前記窒化アルミニウムの重量比は、10%より大きく、かつ、76%以下である請求項1~6の何れか1項に記載のセラミックス焼結体。
- 前記炭化ケイ素と前記窒化アルミニウムとの合計の重量比に対する前記窒化アルミニウムの重量比は、27%以上、かつ、97%以下である請求項1~7の何れか1項に記載のセラミックス焼結体。
- 酸化イットリウムを含む請求項1~8の何れか1項に記載のセラミックス焼結体。
- 炭化ケイ素と窒化アルミニウムとを含むセラミックス焼結体の製造方法であって、
液状のケイ素化合物を含有するケイ素含有原料と、加熱により炭素を生成する有機化合物を含有する炭素含有原料とを混合し、炭化ケイ素前駆体を生成する工程と、
不活性雰囲気下において前記炭化ケイ素前駆体を加熱焼成し、炭化ケイ素原料を生成する工程と、
加水分解型のアルミニウム化合物を含有するアルミニウム含有原料と、加熱により炭素を生成する有機化合物を含有する炭素含有原料と、水とを混合し、窒化アルミニウム前駆体を生成する工程と、
窒素雰囲気下において前記窒化アルミニウム前駆体を加熱焼成し、窒化アルミニウム原料を生成する工程と、
前記炭化ケイ素原料と前記窒化アルミニウム原料とを混合する工程と、
前記炭化ケイ素原料と前記窒化アルミニウム原料との混合物を焼結する工程と、を備え、
前記炭化ケイ素原料と前記窒化アルミニウム原料との混合物に含まれる前記炭化ケイ素と前記窒化アルミニウムとの合計の重量比に対する前記窒化アルミニウムの重量比は、10%より大きく、かつ、97%以下であるセラミックス焼結体の製造方法。 - 前記炭化ケイ素原料と前記窒化アルミニウム原料との混合物に含まれる前記炭化ケイ素と前記窒化アルミニウムとの合計の重量比に対する前記窒化アルミニウムの重量比は、10%より大きく、かつ、51%以下である請求項10に記載のセラミックス焼結体の製造方法。
- 液状のケイ素化合物を含有するケイ素含有原料と、加熱により炭素を生成する有機化合物を含有する炭素含有原料とを混合し、炭化ケイ素前駆体を生成する工程と、
不活性雰囲気下において前記炭化ケイ素前駆体を加熱焼成し、炭化ケイ素原料を生成する工程と、
加水分解型のアルミニウム化合物を含有するアルミニウム含有原料と、加熱により炭素を生成する有機化合物を含有する炭素含有原料と、水とを混合し、窒化アルミニウム前駆体を生成する工程と、
窒素雰囲気下において前記窒化アルミニウム前駆体を加熱焼成し、窒化アルミニウム原料を生成する工程と、
前記炭化ケイ素原料と前記窒化アルミニウム原料とを混合する工程と、
前記炭化ケイ素原料と前記窒化アルミニウム原料との混合物を焼結する工程と、を備え、
前記炭化ケイ素原料と前記窒化アルミニウム原料との混合物に含まれる前記炭化ケイ素と前記窒化アルミニウムとの合計の重量比に対する前記窒化アルミニウムの重量比は、10%より大きく、かつ、97%以下であるセラミックス焼結体の製造方法によって、製造された炭化ケイ素と窒化アルミニウムとを含むセラミックス焼結体。 - 前記炭化ケイ素原料と前記窒化アルミニウム原料との混合物に含まれる前記炭化ケイ素と前記窒化アルミニウムとの合計の重量比に対する前記窒化アルミニウムの重量比は、10%より大きく、かつ、51%以下である請求項12に記載のセラミックス焼結体。
- 曲げ強度が900MPa以上である請求項12又は13に記載のセラミックス焼結体。
- 炭化ケイ素と窒化アルミニウムとを含むセラミックス焼結体の製造方法であって、
液状のケイ素化合物を含有するケイ素含有原料と、加熱により炭素を生成する有機化合物を含有する炭素含有原料と、加水分解型のアルミニウム化合物を含有するアルミニウム含有原料と、水とを混合し、複合前駆体を生成する工程と、
窒素を含む不活性雰囲気下において前記複合前駆体を加熱焼成し、炭化ケイ素及び窒化アルミニウムを含有する複合粉体を生成する工程と、
前記複合粉体を焼結する工程と、を備え、
前記複合粉体に含まれる前記炭化ケイ素と前記窒化アルミニウムとの合計の重量比に対する前記窒化アルミニウムの重量比は、10%より大きく、かつ、97%以下であるセラミックス焼結体の製造方法。 - 前記複合粉体に含まれる前記炭化ケイ素と前記窒化アルミニウムとの合計の重量比に対する前記窒化アルミニウムの重量比は、11%より大きく、かつ、90%以下である請求項15に記載のセラミックス焼結体の製造方法。
- 前記複合粉体と、フェノール樹脂及び酸化イットリウムとを混合する工程とを、さらに備える請求項15又は16に記載のセラミックス焼結体の製造方法。
- 液状のケイ素化合物を含有するケイ素含有原料と、加熱により炭素を生成する有機化合物を含有する炭素含有原料と、加水分解型のアルミニウム化合物を含有するアルミニウム含有原料と、水とを混合し、複合前駆体を生成する工程と、
窒素を含む不活性雰囲気下において前記複合前駆体を加熱焼成し、炭化ケイ素及び窒化アルミニウムを含有する複合粉体を生成する工程と、
前記複合粉体を焼結する工程と、を備え、
前記複合粉体に含まれる前記炭化ケイ素と前記窒化アルミニウムとの合計の重量比に対する前記窒化アルミニウムの重量比は、10%より大きく、かつ、97%以下である製造方法によって、製造された炭化ケイ素と窒化アルミニウムとを含むセラミックス焼結体。 - 前記複合粉体に含まれる前記炭化ケイ素と前記窒化アルミニウムとの合計の重量比に対する前記窒化アルミニウムの重量比は、11%より大きく、かつ、90%以下である請求項18に記載のセラミックス焼結体。
- 前記複合粉体と、フェノール樹脂及び酸化イットリウムとを混合する工程とを、さらに備える請求項18又は19に記載のセラミックス焼結体。
- 熱伝導率は、30W/mK以下であり、断熱材として用いられる請求項18~20の何れか1項に記載のセラミックス焼結体。
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- 2012-04-20 WO PCT/JP2012/060795 patent/WO2012144638A1/ja active Application Filing
- 2012-04-20 US US14/113,084 patent/US20140051566A1/en not_active Abandoned
- 2012-04-20 JP JP2013511079A patent/JP5819947B2/ja not_active Expired - Fee Related
- 2012-04-20 KR KR1020137027687A patent/KR101578988B1/ko active IP Right Grant
- 2012-04-20 CN CN201410567780.8A patent/CN104387074A/zh active Pending
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CN104926310B (zh) * | 2015-06-12 | 2016-11-09 | 中国科学院上海硅酸盐研究所 | 一种氮化铝改性的碳化硅陶瓷粉体及其制备方法 |
JP7495280B2 (ja) | 2020-06-12 | 2024-06-04 | イビデン株式会社 | SiC/SiC複合材の製造方法 |
Also Published As
Publication number | Publication date |
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JP5819947B2 (ja) | 2015-11-24 |
US20150329429A1 (en) | 2015-11-19 |
KR20130135364A (ko) | 2013-12-10 |
CN103608312A (zh) | 2014-02-26 |
CN103608312B (zh) | 2016-08-31 |
EP2700625A4 (en) | 2015-05-27 |
KR101578988B1 (ko) | 2015-12-18 |
CN104387074A (zh) | 2015-03-04 |
US20140051566A1 (en) | 2014-02-20 |
US9522849B2 (en) | 2016-12-20 |
EP2700625B1 (en) | 2018-02-21 |
JPWO2012144638A1 (ja) | 2014-07-28 |
EP2700625A1 (en) | 2014-02-26 |
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