According to the disclosed embodiments, an advanced crucible support system is described that allows for greater heat flow to and from the bottom of a crucible, preferably while also preventing excessive heat from reaching a heat exchanger. In particular, a support base is described that includes one or more vents enabling improved heat flow throughout the system. Also, according to one or more additional embodiments, the functionality of the crucible support is adapted to be leveraged by a crucible manipulating device. For example, the support plate may have a plurality of slots for insertion of a “lifting arm”, such that the entire support plate assembly, as well as the crucible itself while on the support assembly, may be lifted and transported as a single unit.

According to the disclosed embodiments, an advanced crucible support system is described that allows for greater heat flow to and from the bottom of a crucible, preferably while also preventing excessive heat from reaching a heat exchanger. In particular, a support base is described that includes one or more vents enabling improved heat flow throughout the system. Also, according to one or more additional embodiments, the functionality of the crucible support is adapted to be leveraged by a crucible manipulating device. For example, the support plate may have a plurality of slots for insertion of a “lifting arm”, such that the entire support plate assembly, as well as the crucible itself while on the support assembly, may be lifted and transported as a single unit.

The present invention relates to a Ga.sub.2O.sub.3 crystal film deposition method according to HVPE, a deposition apparatus, and a Ga.sub.2O.sub.3 crystal film-deposited substrate using the same. According to an embodiment of the present invention, a Ga.sub.2O.sub.3 crystal film deposition method, which includes a first step of supplying GaCl gas onto a single-crystal semiconductor substrate via a central supply channel and a second step of supplying oxygen and HCl gas onto the single-crystal semiconductor substrate onto which the GaCl gas is supplied, is provided.

The present invention relates to a Ga.sub.2O.sub.3 crystal film deposition method according to HVPE, a deposition apparatus, and a Ga.sub.2O.sub.3 crystal film-deposited substrate using the same. According to an embodiment of the present invention, a Ga.sub.2O.sub.3 crystal film deposition method, which includes a first step of supplying GaCl gas onto a single-crystal semiconductor substrate via a central supply channel and a second step of supplying oxygen and HCl gas onto the single-crystal semiconductor substrate onto which the GaCl gas is supplied, is provided.

Implementations of the present disclosure generally relate to an improved vacuum processing system. In one implementation, the vacuum processing system includes a first transfer chamber coupling to at least one epitaxy process chamber, a second transfer chamber, a transition station disposed between the first transfer chamber and the second transfer chamber, a first plasma-cleaning chamber coupled to the second transfer chamber for removing oxides from a surface of a substrate, and a load lock chamber coupled to the second transfer chamber. The transition station connects to the first transfer chamber and the second transfer chamber, and the transition station includes a second plasma-cleaning chamber for removing carbon-containing contaminants from the surface of the substrate.

A crucible for growing a metal oxide single crystal is provided that can facilitate the balance between the thickness and the strength (hardness) of the constant diameter portion of the crucible and is capable of performing growth of a crystal having a large diameter. The crucible according to the present invention is a crucible for growing a metal oxide single crystal, including a reinforcing belt material provided on an outer periphery of a constant diameter portion of the crucible. It is possible that the crucible has an upper portion having a thickness that is smaller than a thickness of a lower portion of the crucible, and the upper portion of the crucible is the constant diameter portion.

A gallium oxide crystal manufacturing device includes a crucible to hold a gallium oxide source material therein, a crucible support that supports the crucible from below, a crucible support shaft that is connected to the crucible support from below and vertically movably supports the crucible and the crucible support, a tubular furnace core tube that surrounds the crucible, the crucible support and the crucible support shaft, a tubular furnace inner tube that surrounds the furnace core tube, and a resistive heating element including a heat-generating portion placed in a space between the furnace core tube and the furnace inner tube. Melting points of the furnace core tube and the furnace inner tube are not less than 1900° C. A thermal conductivity of a portion of the furnace core tube located directly next to the crucible in a radial direction thereof is higher than a thermal conductivity of the furnace inner tube.

A method for producing a solar crucible includes providing a crucible base body of transparent or opaque fused silica having an inner wall, providing a dispersion containing amorphous SiO.sub.2 particles, applying a SiO.sub.2-containing slip layer to at least a part of the inner wall by using the dispersion, drying the slip layer to form a SiO.sub.2-containing grain layer and thermally densifying the SiO.sub.2-containing grain layer to form a diffusion barrier layer. The dispersion contains a dispersion liquid and amorphous SiO.sub.2 particles that form a coarse fraction and a fine fraction with SiO.sub.2 nanoparticles. The weight percentage of the SiO.sub.2 nanoparticles based on the solids content of the dispersion is in the range between 2 and 15% by weight. The SiO.sub.2-containing grain layer is thermally densified into the diffusion barrier layer through the heating up of the silicon in the crystal growing process.

A vapor deposition apparatus includes an exhaust regulator provided in an exhaust pipe to regulate exhaust of the reaction chamber and including: a hollow frustum upstream baffle having a larger first opening near a reaction chamber than a second opening near an exhaust device; and a hollow frustum downstream baffle provided near the exhaust device with respect to the upstream baffle and having a larger third opening near the reaction chamber than a fourth opening near the exhaust device. The upstream baffle and downstream baffle are designed so that B/A and C/A are 0.33 or less, at least one of B/A and C/A is 0.26 or less, and (B+C)/A is 0.59 or less, where an inner diameter of the exhaust pipe and diameters of the first and third openings are A, a diameter of the second opening is B and a diameter of the fourth opening is C.

A method for manufacturing a silicon carbide single crystal includes: packing a silicon carbide source material into a crucible, the silicon carbide source material having a flowability index of not less than 70 and not more than 100; and sublimating the silicon carbide source material by heating the silicon carbide source material.