Embodiments of the disclosure can include an apparatus for solvothermal crystal growth. The apparatus can include a cylindrical shaped enclosure, a cylindrical heater, a first end closure member, a load-bearing annular insulating member, and a first end plug. The cylindrical heater includes a first end, a second end and a cylindrical wall that extends between the first end and the second end, wherein an interior surface of the cylindrical wall defines a capsule region. The first end closure member is disposed proximate to the first end of the cylindrical heater, the first end closure member being configured to provide axial support for a capsule disposed within the capsule region. The load-bearing annular insulating member is disposed between an inner surface of the cylindrical shaped enclosure and an outer surface of the cylindrical wall of the cylindrical heater. The first end plug is disposed between the first end of the cylindrical heater and the first end closure. The load-bearing annular insulating member or the first end plug comprises a packed-bed ceramic composition, the packed-bed ceramic composition being characterized by a density that is between about 30% and about 98% of a theoretical density of a 100%-dense ceramic having the same composition.

The present invention provides a single crystal growth crucible and a single crystal growth method which can suppress the recrystallization of the raw material gas which has been sublimated on the surface of the raw material and can suppress the generation of different polytypes in single crystal growth. The single crystal growth crucible includes an inner bottom, a crystal mounting part, and a deposition preventing member, wherein a raw material is provided in the inner bottom, the crystal mounting part faces the inner bottom, the deposition preventing member has a first surface comprising metal carbide, a first surface is disposed to face the crystal mounting part, the deposition preventing member is disposed in a central area of the inner bottom in a plan view from the crystal mounting part, and the first surface is disposed in accordance with the position of the surface of the raw material.

A crystal growth apparatus including: a heat source, a crucible including a container body in which a raw material can be received and a lid part on which a seed crystal can be mounted; a first heat insulating part which is disposed externally of the crucible and in which a first through-hole penetrating in a thickness direction is provided; a second heat insulating part which is disposed externally of the first heat insulating part and in which a second through-hole penetrating in a thickness direction is provided; a moving mechanism configured to move the first heat insulating part and the second heat insulating part relative to each other; and a radiation type temperature measuring unit configured to measure a temperature of the crucible via the first through-hole and the second through-hole.

A glass melting component for use in a melt includes at least one guide structure for the conveying and/or nucleation of gas bubbles from the melt. The guide structure is present at least on a surface of the glass melting component which faces the melt during use of the glass melting component.

The present invention relates to a pressure container for crystal production having excellent corrosion-resistance. This pressure container produces crystals within the container using a seed crystal, a mineralizer, a raw material, and ammonia in a super critical state and/or a sub-critical state as a solvent. The pressure container has Ag present over the entire surface of at least the exposed inner surface thereof. The Ag can be disposed by one or a combination of two or more among, for instance, Ag lining, Ag welding, and Ag plating. The mineralizer is preferably a fluorine mineralizer containing no halogen atoms other than fluorine.

A pedestal 103 of the present invention is a pedestal 103 for a seed 102 for crystal growth, in which one main surface 103a to which the seed 102 adheres is flat, and the pedestal has a gas-permeable region 106 which a thickness from the one main surface 103a that is formed to be locally thin.

Provided is an SiC-monocrystal growth crucible that includes, at the interior thereof, a monocrystal installation part and a raw-material installation part, and that serves as a crucible for obtaining an SiC monocrystal by means of sublimation, wherein the gas permeability of a first wall of the crucible, which surrounds at least a portion of a first region positioned closer to the raw-material installation part relative to the monocrystal installation part, is lower than the gas permeability of a second wall of the crucible, which surrounds at least a portion of a second region positioned on the opposite side from the raw-material installation part relative to the monocrystal installation part.

A crucible for growing silicon ingots may include a vessel having a bottom wall and side walls surrounding an inner portion of the vessel. A coating layer is applied to inner surfaces of the bottom wall and the side walls, the coating layer including a temperature-resistant material compatible with ingot growth from molten silicon such as silicon nitride. A patterned protrusion layer is applied at the inner surface of the bottom wall, which includes a matrix consisting of a temperature-resistant material compatible with ingot growth from molten silicon such as silicon nitride. Furthermore, the patterned protrusion layer includes particles of a nucleation enhancing material such as silica, the particles locally protruding from the matrix. The protruding particles may generate a pattern of multiple nucleation points during crystal growth of the ingot. Due to such multiple nucleation points, a dislocation density defect propagation towards a top may be reduced during crystal growth such that, e.g., solar cells produced with wafers sliced from the resulting ingot may have an improved conversion efficiency.

The present disclosure provides a reaction device for a horizontal boat production method. The device comprises a closed reaction tube, and a horizontal boat container, wherein the horizontal boat container include a plurality of first-layer horizontal boat containers and a second-layer horizontal boat container superposed on a bracket device provided on at least one of the first-layer horizontal boat containers.

A device for growing single crystals, in particular of silicon carbide, includes a crucible, which crucible defines an outer lateral surface and moreover delimits an accommodation space with an axial extension between a bottom section and an opening section, wherein the accommodation space is designed for growing the single crystals, wherein the device includes at least one seed crystal layer, wherein the seed crystal layer is assembled from multiple seed crystal plates in a tessellated manner.