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.

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.

An apparatus for fabricating diamond by carbon assembly, which comprises:

a) a hydrocarbon radical generator in operable connection with
b) a mass flow conduit extending from the hydrocarbon radical generator in a) to an interface and into a primary magnetic accelerator containing one or more electromagnets in operable connection with
c) a diamond fabrication reactor comprising a diamond forming deposition substrate.

Also disclosed is a method for fabricating diamond by shockwaves using the disclosed apparatus.

A method and apparatus for processing semiconductor substrates is described herein. The apparatus includes one or more growth monitors disposed within an exhaust system of a deposition chamber. The growth monitors are quartz crystal film thickness monitors and are configured to measure the film thickness grown on the growth monitors while a substrate is being processed within the deposition chamber. The growth monitors are connected to a controller, which adjusts the heating apparatus and gas flow apparatus settings during the processing operations. Measurements from the growth monitors as well as other sensors within the deposition chamber are used to adjust processing chamber models of the deposition chamber as substrates are processed therein.

A method and apparatus for processing semiconductor substrates is described herein. The apparatus includes one or more growth monitors disposed within an exhaust system of a deposition chamber. The growth monitors are quartz crystal film thickness monitors and are configured to measure the film thickness grown on the growth monitors while a substrate is being processed within the deposition chamber. The growth monitors are connected to a controller, which adjusts the heating apparatus and gas flow apparatus settings during the processing operations. Measurements from the growth monitors as well as other sensors within the deposition chamber are used to adjust processing chamber models of the deposition chamber as substrates are processed therein.

A vapor phase epitaxial growth device comprises a reactor vessel and a wafer holder arranged within the reactor vessel. The wafer holder includes a wafer holding surface configured to hold a wafer with a wafer surface oriented substantially vertically downward. The device comprises a first material gas supply pipe configured to supply a first material gas and arranged below the wafer holding surface. The device comprises a second material gas supply pipe configured to supply a second material gas and arranged below the wafer holding surface. The device comprises a gas exhaust pipe configured to exhaust gases and arranged below the wafer holding surface. A distance between the gas exhaust pipe and an axis line passing through a center of the wafer holding surface is greater than distances between the axis line and each of the first material gas supply pipe and the second material gas supply pipe.

A substrate processing apparatus, includes a sealed pressure vessel, such as an Atomic Layer Deposition, ALD, apparatus, a fluid inlet assembly attached to a wall of the sealed pressure vessel, the fluid inlet assembly having a fluid inlet pipe passing through the wall, and a resilient element in the fluid inlet assembly around the fluid inlet pipe coupling the inlet pipe to the wall, where one of an interior surface and an exterior surface of the resilient element sees pressure prevailing within the pressure vessel and the other sees ambient pressure, and where the fluid inlet pipe prevents fluid carried inside from being in contact with the resilient element, and a relating method.

A substrate processing apparatus, includes a sealed pressure vessel, such as an Atomic Layer Deposition, ALD, apparatus, a fluid inlet assembly attached to a wall of the sealed pressure vessel, the fluid inlet assembly having a fluid inlet pipe passing through the wall, and a resilient element in the fluid inlet assembly around the fluid inlet pipe coupling the inlet pipe to the wall, where one of an interior surface and an exterior surface of the resilient element sees pressure prevailing within the pressure vessel and the other sees ambient pressure, and where the fluid inlet pipe prevents fluid carried inside from being in contact with the resilient element, and a relating method.

A film formation apparatus includes a stage, a heater, a mist supply source, a superheated vapor supply source, and a delivery device. The stage is configured to allow a substrate to be mounted thereon. The heater is configured to heat the substrate. The mist supply source is configured to supply mist of a solution that comprises solvent and a film material dissolved in the solvent. The superheated vapor supply source is configured to supply a superheated vapor of a same material as the solvent. The delivery device is configured to deliver the mist and the superheated vapor toward a surface of the substrate to grow a film containing the film material on the surface of the substrate.