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A crucible, which has first member and second cylindrical body, is disposed in a lower chamber. A pedestal is disposed inside the first member, and a seed crystal is fixed to the pedestal. A second heat insulator is provided between an inlet conduit and a crucible. A first heat insulator is provided

A crucible, which has first member and second cylindrical body, is disposed in a lower chamber. A pedestal is disposed inside the first member, and a seed crystal is fixed to the pedestal. A second heat insulator is provided between an inlet conduit and a crucible. A first heat insulator is provided at a halfway portion of the inlet conduit. With these heat insulators, a temperature gradient occurs in the inlet conduit at a portion thereof that is closer to the crucible. A mixture gas is introduced into the crucible. The mixture gas is heated up gradually when passing through the inlet conduit and is introduced into the crucible to form SiC single crystals in high quality.

대표청구항 ▼

What is claimed is: 1. A manufacturing method for producing silicon carbide single crystals, comprising: providing a silicon carbide single-crystal substrate as a seed crystal in a crucible; introducing a mixture gas having a gas including Si and a gas including C into said the crucible, whereby si

What is claimed is: 1. A manufacturing method for producing silicon carbide single crystals, comprising: providing a silicon carbide single-crystal substrate as a seed crystal in a crucible; introducing a mixture gas having a gas including Si and a gas including C into said the crucible, whereby silicon carbide single crystals grow on said the silicon carbide single-crystal substrate, wherein an inlet conduit is provided for introducing the mixture gas into the crucible and includes a heat insulator in a circumferential groove on an outer surface for producing a temperature gradient, and a temperature gradient, which is measured from an outlet end of the inlet conduit to an inlet end of the inlet conduit, is such that a downstream temperature is higher than an upstream temperature. 2. A manufacturing method for producing silicon carbide single crystals according to claim 1, wherein: the inlet conduit has a cross-sectional area that becomes smaller as the inlet conduit approaches the crucible. 3. A manufacturing method for producing silicon carbide single crystals according to claim 1, wherein: a temperature gradient in the inlet conduit is set at 100째 C. /cm or more on an average from the outlet end in the inlet conduit that is adjacent to the crucible to a portion at 500째 C. in the inlet conduit. 4. A manufacturing method for producing silicon carbide single crystals according to claim 1, wherein: a temperature gradient in the inlet conduit is set at 500째 C. /cm or more on an average from the outlet end in the inlet conduit that is adjacent to the crucible to a portion at 500째 C. in the inlet conduit. 5. A manufacturing method for producing silicon carbide single crystals according to claim 1, wherein: a flow velocity of the mixture gas at the outlet end of the inlet conduit that is adjacent to the crucible is set at 50 cm/s or more. 6. A manufacturing method for producing silicon carbide single crystals according to claim 1, wherein: a flow velocity of the mixture gas at the outlet end of the inlet conduit that is adjacent to the crucible is set at 500 cm/s or more. 7. A manufacturing method for producing silicon carbide single crystals, comprising: providing a silicon carbide single-crystal substrate as a seed crystal in a crucible; introducing a mixture gas having a gas including Si and a gas including C into the crucible, whereby silicon carbide single crystals grow on the silicon carbide single-crystal substrate, characterized in that: the mixture gas is mixed with a carrier gas, and the mixture gas and the carrier gas are then introduced into crucible through an inlet conduit including a heat insulator in a circumferential groove on an outer surface of the inlet conduit for introducing the mixture gas into the crucible. 8. A manufacturing method for producing silicon carbide single crystals according to claim 7, wherein: a flow rate including the mixture gas and the carrier gas in the inlet conduit is bigger than that of a gas composed only of the mixture gas in the inlet conduit. 9. A manufacturing method for producing silicon carbide single crystals according to claim 7, wherein: the carrier gas is composed at least one of hydrogen and inert gas. 10. A manufacturing method for producing silicon carbide single crystals comprising: providing a silicon carbide single-crystal substrate as a seed crystal in a crucible; introducing a mixture gas having a gas including Si and a gas including C into the crucible, whereby silicon carbide single crystals grow on the silicon carbide single-crystal substrate, wherein a temperature at an exhaust portion of the crucible through which the mixture gas is exhausted from the crucible is set higher than that at an introducing portion of the crucible through which the mixture gas is introduced into the crucible. 11. A manufacturing method for producing silicon carbide single crystals, comprising: providing a silicon carbide single-crystal substrate as a seed crystal in a crucible; introducing a mixture gas having a gas including Si and a gas including C into the crucible, whereby silicon carbide single crystals grow on the silicon carbide single-crystal substrate; checking a portion in the crucible where deposits caused by the mixture gas are formed using an x-ray apparatus provided outside of the crucible; and raising a temperature of the portion in the crucible with a temperature raising means provided outside of the crucible, which is movable with respect to the crucible, by shifting the temperature raising means. 12. A manufacturing method for producing silicon carbide single crystals, comprising: providing a silicon carbide single-crystal substrate as a seed crystal in a crucible, whereby silicon carbide single crystals grow on the silicon carbide single-crystal substrate; and passing the mixture gas through a trap for solidifying constituents of the mixture gas, wherein the mixture gas is exhausted from a growth room where growth of silicon carbide single crystals on the silicon carbide single-crystal substrate is performed in the crucible, wherein a temperature of the trap is set lower than that of the growth room. 13. A manufacturing method for producing silicon carbide single crystals according to claim 12, wherein the trap is provided as a separated body from the crucible so that the trap is able to be replaced. 14. A manufacturing method for producing silicon carbide single crystals according to claim 12, wherein the trap has an inlet opening communicating with the growth room and an outlet opening communicating with an exhaust conduit that opens to an outside, and at least the outlet opening of the trap is surrounded by a heat insulator.