An oxide film forming device includes: a chamber in which a target workpiece is removably placed; a gas supply unit arranged at a position opposed to a film formation surface of the target workpiece placed in the chamber; and a gas discharge unit arranged to discharge a gas inside the chamber by suction to the outside of the chamber. The gas supply unit has a raw material gas supply nozzle, an ozone gas supply nozzle and an unsaturated hydrocarbon gas supply nozzle with supply ports thereof opposed to the film formation surface of the target workpiece at a predetermined distance away from the film formation surface. A raw material gas, an ozone gas and an unsaturated hydrocarbon gas supplied from the respective supply nozzles are mixed in a space between the supply ports and the film formation surface.

A thin film deposition system includes a vacuum-preloaded gas bearing deposition head positioned in an external environment having an ambient pressure, the deposition head having an output face including a plurality of source openings through which gaseous materials are supplied and one or more exhaust openings. An exhaust pressure at the exhaust openings is less than ambient pressure, and a source pressure at the source openings is greater than that at the exhaust openings, with the pressure at the outermost source openings being greater than ambient pressure. A motion control system moves a substrate unit over the output face in the in-track direction without constraining its motion in a direction normal to the output face to a point where a center of gravity of the substrate unit is beyond the first edge of the output face.

Implementations of the present disclosure generally relate to one or more flow ratio controllers and one or more gas injection inserts in the semiconductor processing chamber. In one implementation, an apparatus includes a first flow ratio controller including a first plurality of flow controllers, a second flow ratio controller including a second plurality of flow controllers, and a gas injection insert including a first portion and a second portion. The first portion includes a first plurality of channels and the second portion includes a second plurality of channels. The apparatus further includes a plurality of gas lines connecting the first and second pluralities of flow controllers to the first and second pluralities of channels. One or more gas lines of the plurality of gas lines are each connected to a channel of the first plurality of channels and a channel of the second plurality of channels.

An apparatus for manufacturing a display apparatus includes a deposition source, a nozzle head, a substrate fixer, and a deposition preventer. The deposition source is outside the chamber and vaporizes or sublimates a deposition material. The nozzle head is in the chamber, is connected to the at least one deposition source, and simultaneously sprays the deposition material onto an entire surface of a display substrate. The substrate fixer is connected to the chamber and moves linearly, with the display apparatus is mounted on the substrate fixer. The deposition preventer is in the chamber surrounding an edge portion of the nozzle head and an edge portion of the substrate fixer. The deposition preventer is heated during a deposition process.

A showerhead utilized within a process chamber includes a first inlet for receiving a first gas from a first source at a center region of an inner plenum defined therein. A plurality of second inlets is defined along a peripheral region of the showerhead for receiving a second gas from a second source. A plurality of conduits couples the edge plenum to an outer edge of the inner plenum so as to supply the second gas to the inner plenum. The first gas creates an inner flow that flows radially outward from the center region to an outer edge of the inner plenum and the second gas supplied by the edge plenum creates a perimeter flow that flows inward from the outer edge of the inner plenum toward the center region. A stagnation point defining an adjustable radius is formed at an interface of the first gas and the second gas. A plurality of outlets are defined across a lower surface of the showerhead and extends a diameter of the inner plenum such that the first gas from the inner flow exits the plurality of outlets from the center region up to the stagnation point and the second gas from the perimeter flow exits the plurality of outlets from the stagnation point to the outer edge.

A coating is deposited on a substrate in a CVD reactor that includes a process chamber and a gas inlet member with a first gas distribution chamber and a second gas distribution chamber separate from the first gas distribution chamber. To deposit heterostructures, in a first step, an inert or a diluent gas is fed into the first gas distribution chamber and a reactive gas containing the elements of a first coating is fed into the second gas distribution chamber. The reactive gas pyrolytically decomposes in the process chamber to form the first coating on the substrate. In a second step, a diluent gas is fed into the second gas distribution chamber and a reactive gas containing the elements of a second coating is fed into the first gas distribution chamber. The reactive gas or gas mixture decomposes in the process chamber to form the second coating on the substrate.

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.

Described herein is a technique capable of improving a uniformity of the characteristics of a film formed on a surface of a substrate by a rotary type apparatus. According to one aspect of the technique, there is provided a substrate processing apparatus including: a process chamber in which a substrate is processed; a substrate support provided in the process chamber and including a plurality of placement parts on which the substrate is placed; a main nozzle provided so as to face a placement part among the plurality of the placement parts and including a first portion where no hole is provided so as to thermally decompose a process gas; and an auxiliary nozzle provided so as to face the placement part and including a second portion where no hole is provided so as to thermally decompose the process gas.

A method for establishing a desired distribution of partial gas pressure along a surface of a substrate when vacuum treating such substrate includes feeding a gas towards the substrate through openings distributed all along the entire periphery of the substrate. The gas is fed or removed at a gas line which communicates exclusively with a set of the openings.

A gas inlet element for a CVD reactor includes a cylindrical main body, which together with an outer wall, forms a gas outlet face. The outer wall surrounds at least one gas distribution chamber. A plurality of gas outlet openings originating in the gas distribution chamber open out into the gas outlet face. A cooling device includes a plurality of cooling channels running adjacently but separately in the outer wall, and the gas outlet openings extend between the cooling channels.