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.

Provided is a SiC chemical vapor deposition apparatus including: a furnace body inside of which a growth space is formed; and a placement table which is positioned in the growth space and has a placement surface on which a SiC wafer is placed, in which the furnace body comprises a first hole which is positioned on an upper portion which faces the placement surface and through which a raw material gas is introduced into the growth space, a second hole which is positioned on a side wall of the furnace body and through which a purge gas flows into the growth space, a third hole which is positioned on the side wall of the furnace body at a lower position than the second hole and discharges the gases in the growth space, and a protrusion which is protrudes towards the growth space from a lower end of the second hole to adjust a flow of the raw material gas.

A process for manufacturing a composite structure comprises: a) providing an initial substrate made of monocrystalline silicon carbide, b) epitaxially growing a monocrystalline silicon carbide donor layer on the initial substrate to form a donor substrate 111, c) implanting ions into the donor layer to form a buried brittle plane defining the the donor layer, d) depositing, using liquid injection-chemical vapor deposition at a temperature below 1000° C., a carrier layer on the donor layer, the carrier layer comprising an at least partially amorphous SiC matrix, e) separating the donor substrate along the brittle plane to form an intermediate composite structure comprising the donor layer on the carrier layer f) heat treating the intermediate composite structure at a temperature of between 1000° C. and 1800° C. to crystallize the carrier layer and form the polycrystalline carrier substrate, and g) applying mechanical and/or chemical treatment(s) of the composite structure.

An epitaxy substrate and a method of manufacturing the same are provided. The epitaxy substrate includes a silicon substrate and a silicon carbide layer. The silicon substrate has a first surface and a second surface opposite to each other, and the first surface is an epitaxy surface. The silicon carbide layer is located in the silicon substrate, and a distance between the silicon carbide layer and the first surface is between 100 angstroms (Å) and 500 angstroms.

A silicon carbide epitaxial substrate includes a silicon carbide single crystal substrate and a silicon carbide layer. In a direction parallel to a central region, a ratio of a standard deviation of a carrier concentration of the silicon carbide layer to an average value of the carrier concentration of the silicon carbide layer is less than 5%. The average value of the carrier concentration is more than or equal to 1×10.sup.14 cm.sup.−3 and less than or equal to 5×10.sup.16 cm.sup.−3. In the direction parallel to the central region, a ratio of a standard deviation of a thickness of the silicon carbide layer to an average value of the thickness of the silicon carbide layer is less than 5%. The central region has an arithmetic mean roughness (Sa) of less than or equal to 1 nm. The central region has a haze of less than or equal to 50.

Various embodiments of the present disclosure are directed towards a semiconductor device including a gate electrode over a semiconductor substrate. An epitaxial source/drain layer is disposed on the semiconductor substrate and is laterally adjacent to the gate electrode. The epitaxial source/drain layer comprises a first dopant. A diffusion barrier layer is between the epitaxial source/drain layer and the semiconductor substrate. The diffusion barrier layer comprises a barrier dopant that is different from the first dopant.

An object of the present invention is to provide a high-quality SiC semiconductor device. In order to solve the above problem, the present invention comprises a method for producing a SiC semiconductor device, comprising a growth step of forming a growth layer on a workpiece comprising SiC single crystals, a device formation step of forming at least a portion of a SiC semiconductor device in the growth layer, and a separation step of separating at least a portion of the SiC semiconductor device from the workpiece.

A method of manufacturing a SiC epitaxial wafer in which a SiC epitaxial layer is formed on a SiC single crystal substrate, the method including identifying a total number of large-pit defects caused by micropipes in the SiC single crystal substrate and large-pit defects caused by substrate carbon inclusions, both of which are contained in the SiC epitaxial layer, using microscopic and photoluminescence images. Also disclosed is a method of manufacturing a SiC epitaxial wafer in which a SiC epitaxial layer is formed on a single crystal substrate, the method including identifying locations of the large-pit defects caused by micropipes in the SiC single crystal substrate and the large-pit defects caused by substrate carbon inclusions in the SiC epitaxial layer, using microscopic and photoluminescence images.

A method of manufacturing a silicon carbide epitaxial substrate includes: preparing a silicon carbide single-crystal substrate having a polytype of 4H and having a principal surface inclined at an angle θ from a {0001} plane in a <11-20> direction; growing a silicon carbide epitaxial layer on the principal surface having a basal plane dislocation, the basal plane dislocation having a portion extending in a <1-100> direction and a portion extending in a <11-20> direction; and irradiating the silicon carbide epitaxial layer with an ultraviolet light having a predetermined power and a predetermined wavelength for a predetermined period of time to stabilize the basal plane dislocation. After the irradiating, the basal plane dislocation does not move even when the basal plane dislocation is irradiated with an ultraviolet light having a power of 270 mW and a wavelength of 313 nm for 10 seconds.

A silicon carbide epitaxial substrate according to a present disclosure includes a silicon carbide substrate and a silicon carbide epitaxial layer disposed on the silicon carbide substrate. The silicon carbide epitaxial layer includes a boundary surface in contact with the silicon carbide substrate and a main surface opposite to the boundary surface. The main surface has an outer circumferential edge, an outer circumferential region extending within 5 mm from the outer circumferential edge, and a central region surrounded by the outer circumferential region. When an area density of double Shockley stacking faults in the outer circumferential region is defined as a first area density, and an area density of double Shockley stacking faults in the central region is defined as a second area density, the first area density is five or more times as large as the second area density, the second area density is 0.2 cm.sup.−2 or more.