A method of growing a semi-insulating SiC single crystal ingot, the method comprising the steps of: (1) placing a dopant coated with silicon carbide (SiC) and a carbon-based material into a reaction vessel containing a seed crystal fixed thereto; and (2) growing a SiC single crystal on the seed crystal, thereby yielding a high-quality semi-insulating SiC single crystal ingot with a uniform thickness-based doping concentration. In addition, another embodiment relates to a method of growing a semi-insulating silicon carbide single crystal ingot, the method comprising the steps of: (a) placing in a reaction vessel, a composition comprising a carbon-containing polymer resin, a solvent, a dopant, and silicon carbide (SiC); (b) solidifying the composition; and (c) growing a SiC single crystal ingot on a seed crystal fixed to the reaction vessel, thereby yielding a high-quality semi-insulating SiC single crystal ingot with a uniform thickness-based doping concentration.

A shielding member, wherein the shielding member is formed of at least one of structure which has a non-flat plate shape having an inclined surface, and the inclined surface is located on a side of a substrate support part when the shielding member is disposed in a single crystal growth device, wherein the single crystal growth device comprising: a crystal growth container; a source storage part that is positioned at a lower inner part of the crystal growth container; the substrate support part, wherein the support part is disposed above the source storage part and supports a substrate to make the substrate face the source storage part; and a heating device that is disposed on an outer circumference of the crystal growth container, wherein the shielding member is disposed between the source storage part and the substrate support part, and wherein a single crystal of a source is grown on the substrate by sublimating the source from the source storage part.

Systems and methods for providing controllable substrate-to-source arrangements in a Molecular Beam Epitaxy (MBE) system to selectively adjust a distance, orientation, or other geometric configuration as between the source(s) and substrate(s) used in epitaxial growth systems are described herein. It has been found that by controllably adjusting height, crucible type and angle, and other processing conditions, that extremely high thickness uniformity can be accomplished in epitaxially grown wafers.

The disclosure refers to a furnace apparatus, in particular a furnace apparatus for growing crystals, in particular for growing SiC crystals. The furnace apparatus includes a furnace unit, where the furnace unit includes a furnace housing, at least one crucible unit where the crucible unit is arranged inside the furnace housing, where the crucible unit includes a crucible housing, where the housing has an outer surface and an inner surface, where the inner surface at least partially defines a crucible volume, where a receiving space for receiving a source material is arranged or formed inside the crucible volume, where a seed holder unit for holding a defined seed wafer is arranged inside the crucible volume, and at least one heating unit for heating the source material, where the receiving space for receiving the source material is at least in parts arranged between the heating unit and the seed holder unit.

A silicon carbide crystal includes a seed layer, a bulk layer and a stress buffering structure formed between the seed layer and the bulk layer. The seed layer, the bulk layer and the stress buffering structure are each formed with a dopant that cycles between high and low dopant concentration. The stress buffering structure includes a plurality of stacked buffer layers and a transition layer over the buffer layers. The buffer layer closest to the seed layer has the same variation trend of the dopant concentration as the buffer layer closest to the transition layer, and the dopant concentration of the transition layer is equal to the dopant concentration of the seed layer.

Various embodiments provide Molten Target Sputtering (MTS) methods and devices. The various embodiments may provide increases in the kinetic energy, increases in the energy latency, and/or increases in the flux density of molecules for better crystal formation at low temperature operation. The various embodiment MTS methods and devices may enable the growth of a single crystal Si.sub.1-xGe.sub.x film on a substrate heated to less than about 500 C. The various embodiment MTS methods and devices may provide increases in the kinetic energy, increases in the energy latency, and/or increases in the flux density of molecules without requiring the addition of extra systems.

A high-purity semi-insulating silicon carbide crystal growing apparatus and a method therefor are provided, the apparatus comprising a growth crucible, a bottom part of the growth crucible having inserted a gas pipe, a top part of the growth crucible being provided with a growth crucible cover, a feedstock crucible having a bowl-shaped structure being disposed in the growth crucible, an upper part of the feedstock crucible being provided with a baffle, a bottom part of the feedstock crucible being provided with a ring-shaped supporting feedstock crucible bottom foot, the diameter of the feedstock crucible bottom foot being the diameter of the feedstock crucible, and the feedstock crucible bottom foot having disposed thereon 8-36 evenly distributed gas holes.

A method of growing a semi-insulating SiC single crystal ingot, the method comprising the steps of: (1) placing a dopant coated with silicon carbide (SiC) and a carbon-based material into a reaction vessel containing a seed crystal fixed thereto; and (2) growing a SiC single crystal on the seed crystal, thereby yielding a high-quality semi-insulating SiC single crystal ingot with a uniform thickness-based doping concentration. In addition, another embodiment relates to a method of growing a semi-insulating silicon carbide single crystal ingot, the method comprising the steps of: (a) placing in a reaction vessel, a composition comprising a carbon-containing polymer resin, a solvent, a dopant, and silicon carbide (SiC); (b) solidifying the composition; and (c) growing a SiC single crystal ingot on a seed crystal fixed to the reaction vessel, thereby yielding a high-quality semi-insulating SiC single crystal ingot with a uniform thickness-based doping concentration.

A system for simultaneously manufacturing more than one single crystal of a semiconductor material by physical vapor transport (PVT) includes a plurality of reactors and a common vacuum channel connecting at least a pair of reactors of the plurality of reactors. Each reactor has an inner chamber adapted to accommodate a PVT growth structure for growth of a single semiconductor crystal. The common vacuum channel is connectable to a vacuum pump system for creating and/or controlling a common gas phase condition in the inner chambers of the pair of reactors.

A silicon carbide crystal and a method for manufacturing the same are disclosed. The silicon carbide crystal includes a seed layer, a bulk layer, and a stress buffering structure formed between the seed layer and the bulk layer. The seed layer, the bulk layer, and the stress buffering structure are each formed with a dopant that cycles between high and low concentration. Therefore, the crystal defects can be significantly reduced.