A method of single crystal growth includes disposing a polycrystalline source material in a chamber of a single crystal growth apparatus, disposing a seed layer in the chamber of the single crystal growth apparatus, wherein the seed layer is fixed below a lid of the single crystal growth apparatus, heating the polycrystalline source material by a heater of the single crystal growth apparatus to deposit a semiconductor material layer on the seed layer, and after depositing the semiconductor material layer, providing a coolant gas at a backside of the lid to cool down the seed layer and the semiconductor material layer.

Provided is a susceptor which makes it possible to increase the circumferential flatness uniformity of an epitaxial layer of an epitaxial silicon wafer. A susceptor 100 is provided with a concave counterbore portion on which a silicon wafer W is placed, and the radial distance L between the center of the susceptor and an opening edge of the counterbore portion varies at 90° periods in the circumferential direction. Meanwhile, when the angle at which the radial distance L is minimum is 0°, the radial distance L is a minimum value L.sub.1 at 90°, 180°, and 270°; and the radial distance L is a maximum value L.sub.2 at 45°, 135°, 225°, and 315°. Accordingly, the pocket width L.sub.p also varies in conformance with the variations of the radial distance L. The opening edge 110C describes four elliptical arcs being convex radially outward when the susceptor 100 is viewed from above.

Provided is a susceptor which makes it possible to increase the circumferential flatness uniformity of an epitaxial layer of an epitaxial silicon wafer. A susceptor 100 is provided with a concave counterbore portion on which a silicon wafer W is placed, and the radial distance L between the center of the susceptor and an opening edge of the counterbore portion varies at 90° periods in the circumferential direction. Meanwhile, when the angle at which the radial distance L is minimum is 0°, the radial distance L is a minimum value L.sub.1 at 90°, 180°, and 270°; and the radial distance L is a maximum value L.sub.2 at 45°, 135°, 225°, and 315°. Accordingly, the pocket width L.sub.p also varies in conformance with the variations of the radial distance L. The opening edge 110C describes four elliptical arcs being convex radially outward when the susceptor 100 is viewed from above.

A crystal raw material loading device and a crystal growth device includes a plurality of bearing units which are arranged adjacent to each other horizontally in turn, and the multiple bearing units include a first bearing unit arranged at one end of a small plane far away from the seed crystal bearing device. Along the direction from one end of the small plane far away from the seed crystal to one end of the small plane close to the seed crystal, from the first bearing unit to the bearing unit on the side of the small plane close to the seed crystal, the height of the raw material that can be carried by each bearing unit is reduced in turn.

A crystal raw material loading device and a crystal growth device includes a plurality of bearing units which are arranged adjacent to each other horizontally in turn, and the multiple bearing units include a first bearing unit arranged at one end of a small plane far away from the seed crystal bearing device. Along the direction from one end of the small plane far away from the seed crystal to one end of the small plane close to the seed crystal, from the first bearing unit to the bearing unit on the side of the small plane close to the seed crystal, the height of the raw material that can be carried by each bearing unit is reduced in turn.

The present invention addresses the issue of providing: an SiC substrate having a dislocation conversion layer that can reduce resistance; and a novel technology pertaining to SiC semiconductors. This SiC substrate and SiC semiconductor device comprise a dislocation conversion layer 12 having a doping concentration of at least 1×10.sup.15 cm.sup.−3. As a result of comprising a dislocation conversion layer 12 having this kind of doping concentration: expansion of basal plane dislocations and the occurrence of high-resistance stacking faults can be suppressed; and resistance when SiC semiconductor devices are produced can be reduced.

The present invention addresses the issue of providing: an SiC substrate having a dislocation conversion layer that can reduce resistance; and a novel technology pertaining to SiC semiconductors. This SiC substrate and SiC semiconductor device comprise a dislocation conversion layer 12 having a doping concentration of at least 1×10.sup.15 cm.sup.−3. As a result of comprising a dislocation conversion layer 12 having this kind of doping concentration: expansion of basal plane dislocations and the occurrence of high-resistance stacking faults can be suppressed; and resistance when SiC semiconductor devices are produced can be reduced.

Organosilicon chemistry, polymer derived ceramic materials, and methods. Such materials and methods for making polysilocarb (SiOC) and Silicon Carbide (SiC) materials having 3-nines, 4-nines, 6-nines and greater purity. Processes and articles utilizing such high purity SiOC and SiC.

Organosilicon chemistry, polymer derived ceramic materials, and methods. Such materials and methods for making polysilocarb (SiOC) and Silicon Carbide (SiC) materials having 3-nines, 4-nines, 6-nines and greater purity. Processes and articles utilizing such high purity SiOC and SiC.

Provided is a polycrystalline SiC molded body wherein the resistivity is not more than 0.050 Ωcm and, when the peak strength in a wave number range of 760-780 cm.sup.−1 in a Raman spectrum is regarded as “A” and the peak strength in a wave number range of 790-800 cm.sup.−1 in the Raman spectrum is regarded as “B”, then the peak ratio (A/B) is not more than 0.100.