The device (420) is for supporting substrates in a reaction chamber of an epitaxial reactor; it comprises: a disc-shaped element (422) having a first face (422A) adapted to be upperly positioned when the device (420) is being used and a second face (422B) adapted to be lowerly positioned when the device (420) is being used, said disc-shaped element (422) being adapted to receive a gas flow (F) to rotate the device (420) about an axis (X) thereof, a substrate-supporting element (424) in a single piece with said disc-shaped element (422) and preferably adjacent to said first face (422A), and a shaft (426) coaxial to said disc-shaped element (422), in a single piece with said disc-shaped element (422) and having a first end (426A) at said second face (422B); said shaft (426) has at a second end (426 B) thereof at least a protrusion (428 A, 428B, 428C) whose rotation is adapted to be detected by a pyrometer (430) or a thermographic camera.

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 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.

The present disclosure describes a method for controlling radiation conditions and an example system for performing the method. The method includes sending a first setting to configure a radiation device to provide radiation to a substrate undergoing a process operation in a process chamber of the radiation device. The method further includes receiving radiation energy data measured at a plurality of locations of the process chamber and receiving measurement data measured on the substrate during the process operation. The method further includes in response to a variance of the radiation energy data being above a first predetermined threshold and in response to a difference between reference data and the measurement data being above a second predetermined threshold, sending a second setting to configure the radiation device to provide radiation to the substrate.

A manufacturing apparatus for a group-III nitride crystal, the manufacturing apparatus includes: a raw material chamber that produces therein a group-III element oxide gas; and a nurturing chamber in which a group-III element oxide gas supplied from the raw material chamber and a nitrogen element-containing gas react therein to produce a group-III nitride crystal on a seed substrate, wherein an angle that is formed by a direction along a shortest distance between a forward end of a group-III element oxide gas supply inlet to supply the group-III element oxide gas into the nurturing chamber and an outer circumference of the seed substrate placed in the nurturing chamber, and a surface of the seed substrate is denoted by “θ”, wherein a diameter of the group-Ill element oxide gas supply inlet is denoted by “S”, wherein a distance between a surface, on which the seed substrate is placed, of a substrate susceptor that holds the seed substrate and a forward end of a first carrier gas supply inlet to supply a first carrier gas into the nurturing chamber is denoted by “L.sub.1”, wherein a distance between the forward end of the first carrier gas supply inlet and the forward end of the group-III element oxide gas supply inlet is denoted by “M.sub.1”, wherein a diameter of the seed substrate is denoted by “k”, and wherein following Eqs. (1) to (4), 0°<θ<90° (1), 0.21≤S/k≤0.35 (2), 1.17≤(L.sub.1+M.sub.1)/k≤1.55 (3), k=2*(L.sub.1+M.sub.1)/tan θ+S (4) are satisfied.

Methods for determining suitability of a silicon substrate for epitaxy and/or for determining slip resistance during epitaxy and post-epitaxy thermal treatment are disclosed. The methods involve evaluating different substrates of the epitaxial wafers by imaging the wafer by infrared depolarization. An infrared depolarization parameter is generated for each epitaxial wafer. The parameters may be compared to determine which substrates are well-suited for epitaxial and/or post-epi heat treatments.

Methods for determining suitability of a silicon substrate for epitaxy and/or for determining slip resistance during epitaxy and post-epitaxy thermal treatment are disclosed. The methods involve evaluating different substrates of the epitaxial wafers by imaging the wafer by infrared depolarization. An infrared depolarization parameter is generated for each epitaxial wafer. The parameters may be compared to determine which substrates are well-suited for epitaxial and/or post-epi heat treatments.

Methods for determining suitability of Czochralski growth conditions to produce silicon substrates for epitaxy. The methods involve evaluating substrates sliced from ingots grown under different growth conditions (e.g., impurity profiles) by imaging the wafer by infrared depolarization. An infrared depolarization parameter is generated for each epitaxial wafer. The parameters may be compared to determine which growth conditions are well-suited to produce substrates for epitaxial and/or post-epi heat treatments.

Methods for determining suitability of Czochralski growth conditions to produce silicon substrates for epitaxy. The methods involve evaluating substrates sliced from ingots grown under different growth conditions (e.g., impurity profiles) by imaging the wafer by infrared depolarization. An infrared depolarization parameter is generated for each epitaxial wafer. The parameters may be compared to determine which growth conditions are well-suited to produce substrates for epitaxial and/or post-epi heat treatments.

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.