An apparatus for forming semiconductor films can include a horizontal flow reactor including an upper portion and a lower portion that are moveably coupled to one another so as to separate from one another in an open position and so as to mate together in a closed position to form a reactor chamber. A central injector column can penetrate through the upper portion of the horizontal flow reactor into the reactor chamber, the central injector column configured to allow metalorganic precursors into the reactor chamber in the closed position. A heated metalorganic precursor line can be coupled to the central injector column and configured to heat a low vapor pressure metalorganic precursor vapor contained in the heated metalorganic precursor line upstream of the central injector column to a temperature range between about 70° C. and 200° C.

A Metalorganic chemical vapor phase epitaxy or vapor phase deposition apparatus, having a first gas source system, a reactor, an exhaust gas system, and a control unit, wherein the first gas source system has a carrier gas source, a bubbler with an organometallic starting compound, and a first supply section leading to the reactor either directly or through a first control valve, the carrier gas source is connected to an inlet of the bubbler through a first mass flow controller by a second supply section, an outlet of the bubbler is connected to the first supply section, and the carrier gas source is connected to the first supply section through a second mass flow controller by a third supply section, the first supply section is connected to an inlet of the reactor through a third mass flow controller.

A Metalorganic chemical vapor phase epitaxy or vapor phase deposition apparatus, having a first gas source system, a reactor, an exhaust gas system, and a control unit, wherein the first gas source system has a carrier gas source, a bubbler with an organometallic starting compound, and a first supply section leading to the reactor either directly or through a first control valve, the carrier gas source is connected to an inlet of the bubbler through a first mass flow controller by a second supply section, an outlet of the bubbler is connected to the first supply section, and the carrier gas source is connected to the first supply section through a second mass flow controller by a third supply section, the first supply section is connected to an inlet of the reactor through a third mass flow controller.

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.

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 method of making 2D material such as graphene includes introducing a purge gas into a gas confining space within a reaction chamber to purge the gas confining space of oxygen; introducing a donor gas into the gas confining space within the reaction chamber; moving a forming layer within the gas confining space within the reaction chamber when the donor gas is within the gas confining space; and heating the forming layer within the gas confining space to a temperature sufficient to form 2D material while the gas confining space is open to a surrounding atmosphere.

A method of making 2D material such as graphene includes introducing a purge gas into a gas confining space within a reaction chamber to purge the gas confining space of oxygen; introducing a donor gas into the gas confining space within the reaction chamber; moving a forming layer within the gas confining space within the reaction chamber when the donor gas is within the gas confining space; and heating the forming layer within the gas confining space to a temperature sufficient to form 2D material while the gas confining space is open to a surrounding atmosphere.

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.

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 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.