The present invention relates to a susceptor including a substrate including a carbon material and having one main surface on which a silicon water is to be placed, and another main surface facing the one main surface, in which an entire surface of the substrate is covered with a thin film including silicon carbide, the one main surface has an emissivity variation of 3% or less, and a ratio of an average emissivity between the one main surface and the another main surface facing the one main surface is from 1:1 to 1:0.8.

A method of manufacturing a semiconductor device, includes attaching a first susceptor to a film forming apparatus, measuring a magnitude of a warp of the first susceptor, setting a first initial film formation condition as a film formation condition of the film forming apparatus in accordance with the measured magnitude of the warp of the first susceptor, and placing a plurality of first wafers on the first susceptor and forming a first film on the plurality of first wafers under the film formation condition. The setting of the first initial film formation condition includes reading the first initial film formation condition from a recording medium storing a database. The database includes a plurality of pieces of data in which magnitudes of warps of susceptors are associated with initial film formation conditions for forming the first film.

A wafer carrier includes a pocket sized and shaped to accommodate a wafer, the pocket having a base and a substantially circular perimeter, and a removable orientation marker, the removable orientation marker comprising an outer surface and an inner surface, the outer surface having an arcuate form sized and shaped to mate with the substantially circular perimeter of the pocket, and the inner surface comprising a flat face, wherein the removable orientation marker further comprises a notch at a first end of the flat face.

A wafer carrier includes a pocket sized and shaped to accommodate a wafer, the pocket having a base and a substantially circular perimeter, and a removable orientation marker, the removable orientation marker comprising an outer surface and an inner surface, the outer surface having an arcuate form sized and shaped to mate with the substantially circular perimeter of the pocket, and the inner surface comprising a flat face, wherein the removable orientation marker further comprises a notch at a first end of the flat face.

A method deposits an epitaxial layer on a front side of a semiconductor wafer having monocrystalline material. The method includes: providing the semiconductor wafer; arranging the semiconductor wafer on a susceptor; heating the semiconductor wafer to a deposition temperature using thermal radiation directed to the front side and to the rear side of the semiconductor wafer; conducting a deposition gas over the front side of the semiconductor wafer; and selectively reducing an intensity of a portion of the thermal radiation that is directed to the rear side of the semiconductor wafer, as a result of which first partial regions at an edge of the semiconductor wafer, in the first partial regions a growth rate of the epitaxial layer is greater than in adjacent second partial regions given uniform temperature of the semiconductor wafer owing to an orientation of the monocrystalline material, are heated more weakly.

The manufacturing apparatus for a group-III compound semiconductor crystal according to the present disclosure comprises a reaction container. The reaction container has a raw material reaction section, a crystal growth section, and a gas flow channel. The raw material reaction section has a raw material reaction chamber, and a raw material gas nozzle. The crystal growth section has a substrate supporting member, and reactive gas nozzles. The gas flow channel includes a first flow channel, a second flow channel, and a connection portion. The first flow channel has a first opening, and the second flow channel has a second opening. The area of the second opening is configured to be larger than the area of the first opening. The connection portion connects the first opening and the second opening with each other. The gas flow channel forms a gas flow path in the reaction container. The substrate supporting member is disposed inside the gas flow path and located on the downstream side of the first opening.

The manufacturing apparatus for a group-III compound semiconductor crystal according to the present disclosure comprises a reaction container. The reaction container has a raw material reaction section, a crystal growth section, and a gas flow channel. The raw material reaction section has a raw material reaction chamber, and a raw material gas nozzle. The crystal growth section has a substrate supporting member, and reactive gas nozzles. The gas flow channel includes a first flow channel, a second flow channel, and a connection portion. The first flow channel has a first opening, and the second flow channel has a second opening. The area of the second opening is configured to be larger than the area of the first opening. The connection portion connects the first opening and the second opening with each other. The gas flow channel forms a gas flow path in the reaction container. The substrate supporting member is disposed inside the gas flow path and located on the downstream side of the first opening.

The present disclosure provides a semiconductor processing apparatus according to one embodiment. The semiconductor processing apparatus includes a chamber; a base station located in the chamber for supporting a semiconductor substrate; a preheating assembly surrounding the base station; a first heating element fixed relative to the base station and configured to direct heat to the semiconductor substrate; and a second heating element moveable relative to the base station and operable to direct heat to a portion of the semiconductor substrate.

The present disclosure provides a semiconductor processing apparatus according to one embodiment. The semiconductor processing apparatus includes a chamber; a base station located in the chamber for supporting a semiconductor substrate; a preheating assembly surrounding the base station; a first heating element fixed relative to the base station and configured to direct heat to the semiconductor substrate; and a second heating element moveable relative to the base station and operable to direct heat to a portion of the semiconductor substrate.

A pedestal 103 of the present invention is a pedestal 103 for a seed 102 for crystal growth, in which one main surface 103a to which the seed 102 adheres is flat, and the pedestal has a gas-permeable region 106 which a thickness from the one main surface 103a that is formed to be locally thin.