A silicon carbide single crystal manufacturing apparatus includes a crucible constituted by a crucible body and a crucible lid and a base having a crucible lid side surface supported by the lower surface of the crucible lid, and a seed crystal mounting surface on which the seed crystal is mounted and which is a surface on the opposite side of the crucible lid side surface, wherein the base is made of graphite material, the area of the seed crystal mounting surface is larger than the area of the crucible lid side surface, and the base has at least of a portion in which the cross-sectional area orthogonal to the vertical direction connecting the crucible lid side surface and the seed crystal mounting surface is gradually reduced, and a portion that is getting smaller gradually, from the surface of the seed crystal mounting surface toward the crucible lid side surface.

A silicon carbide single crystal manufacturing apparatus includes a crucible constituted by a crucible body and a crucible lid and a base having a crucible lid side surface supported by the lower surface of the crucible lid, and a seed crystal mounting surface on which the seed crystal is mounted and which is a surface on the opposite side of the crucible lid side surface, wherein the base is made of graphite material, the area of the seed crystal mounting surface is larger than the area of the crucible lid side surface, and the base has at least of a portion in which the cross-sectional area orthogonal to the vertical direction connecting the crucible lid side surface and the seed crystal mounting surface is gradually reduced, and a portion that is getting smaller gradually, from the surface of the seed crystal mounting surface toward the crucible lid side surface.

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 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.

Provides a method for adjusting a thermal field of silicon carbide single crystal growth, and steps comprise: (A) screening a silicon carbide source, and filling into a bottom of a graphite crucible; (B) placing a guide inside the graphite crucible; (C) placing a rigid heat conductive material on the guide, so that a gap between the guide and a crucible wall of the graphite crucible is reduced; (D) fixing a seed crystal on a top of the graphite crucible; (E) placing the graphite crucible equipped with the silicon carbide source and the seed crystal in an induction high-temperature furnace used by physical vapor transport method; (F) performing a silicon carbide crystal growth process; and (G) obtaining a silicon carbide single crystal.

Provides a method for adjusting a thermal field of silicon carbide single crystal growth, and steps comprise: (A) screening a silicon carbide source, and filling into a bottom of a graphite crucible; (B) placing a guide inside the graphite crucible; (C) placing a rigid heat conductive material on the guide, so that a gap between the guide and a crucible wall of the graphite crucible is reduced; (D) fixing a seed crystal on a top of the graphite crucible; (E) placing the graphite crucible equipped with the silicon carbide source and the seed crystal in an induction high-temperature furnace used by physical vapor transport method; (F) performing a silicon carbide crystal growth process; and (G) obtaining a silicon carbide single crystal.

According to the present invention, there is provided a SiC epitaxial wafer including: a 4H-SiC single crystal substrate which has a surface with an off angle with respect to a c-plane as a main surface and a bevel part on a peripheral part; and a SiC epitaxial layer having a film thickness of 20 μm or more, which is formed on the 4H-SiC single crystal substrate, in which a density of an interface dislocation extending from an outer peripheral edge of the SiC epitaxial layer is 10 lines/cm or less.

According to the present invention, there is provided a SiC epitaxial wafer including: a 4H-SiC single crystal substrate which has a surface with an off angle with respect to a c-plane as a main surface and a bevel part on a peripheral part; and a SiC epitaxial layer having a film thickness of 20 μm or more, which is formed on the 4H-SiC single crystal substrate, in which a density of an interface dislocation extending from an outer peripheral edge of the SiC epitaxial layer is 10 lines/cm or less.

Disclosed is a method for synthesizing two-dimensional (2D) silicon carbide and other materials. The method includes the use of hexagonal SiC precursor in a wet exfoliation technique. The method may also include synthesizing two-dimensional (2D) silicon carbide by a chemical vapor deposition method, or a combination of a liquid exfoliation technique and a chemical vapor deposition method.

An apparatus for growing semiconductor wafers, in particular of silicon carbide, wherein a chamber houses a collection container and a support or susceptor arranged over the container. The support is formed by a frame surrounding an opening accommodating a plurality of arms and a seat. The frame has a first a second surface, opposite to each other, with the first surface of the frame facing the support. The arms are formed by cantilever bars extending from the frame into the opening, having a maximum height smaller than the frame, and having at the top a resting edge. The resting edges of the arms define a resting surface that is at a lower level than the second surface of the frame. The seat has a bottom formed by the resting surface.