There is provided a technique of cleaning an inside of a process container, including: (a) removing substances adhered in a process container set at a first temperature by supplying a first gas at a first flow rate into the process container and exhausting the inside of the process container; (b) physically desorbing and removing residual fluorine in the process container set at a second temperature by supplying a second gas at a second flow rate into the process container and exhausting the inside of the process container; and (c) chemically desorbing and removing residual fluorine in the process container set at a third temperature by supplying a third gas at a third flow rate into the process container and exhausting the inside of the process container.

Methods of depositing silicon nitride on a surface of a substrate are disclosed. The methods include using an intermediate treatment process to increase a quality of the silicon nitride layer and a second treatment process.

A vaporization system includes: a vaporization device that is configured to vaporize a liquid material and that includes an inlet port through which the liquid material is introduced and an outlet port through which vaporized gas generated by vaporizing the liquid material is discharged; at least one first fixing screw with which at least one of the inlet port or the outlet port is screwed and fixed onto a base; at least one pipe member that is configured to communicate with the fixed port and through which the vaporized gas or the liquid material flows; and at least one second fixing screw with which the at least one pipe member is screwed and fixed onto the fixed port with a seal member interposed between the at least one pipe member and the fixed port.

An MOCVD system for growing a semiconductor layer on a substrate is provided. The MOCVD system includes an MOCVD growth chamber defined by a jacket having an interior surface and an exterior surface; a water flow chamber surrounding an exterior surface of the jacket of the MOCVD growth chamber; an electronic control system, wherein the electronic control system facilitates pulsed growth of the semiconductor layer; a supply tube comprising a head formed from a hollow structure defining a fitting end and an opposite, shower end, wherein the fitting end has an initial diameter that is less than a diameter at the shower end; and a susceptor configured to hold the substrate and facing the shower end of the supply tube, wherein the MOCVD system operates at a temperature greater than or equal to 1500° C.

A deposition or cleaning apparatus comprising an outer vacuum chamber and a reaction chamber inside the outer chamber forming a double chamber structure. The reaction chamber is configured to move between a processing position and a lowered position inside the outer vacuum chamber, the lowered position being for loading one or more substrates into the reaction chamber.

Methods and apparatus for processing substrates are provided herein. In some embodiments, an apparatus for processing substrates includes a chamber body enclosing a processing volume, the chamber body comprising a chamber floor, a chamber wall coupled to the chamber floor, and a chamber lid removably coupled to the chamber wall, wherein at least one of the chamber floor, the chamber wall, and the chamber lid comprise passages for a flow of a thermal control media; a heater plate disposed adjacent to and spaced apart from the chamber floor; a sleeve disposed adjacent to and spaced apart from the chamber wall, the sleeve supported by the heater plate; and a first sealing element disposed at a first interface between the chamber wall and the chamber lid.

A substrate treatment apparatus includes: a reaction tube including a substrate treatment region in which a substrate is treated; and a furnace opening member disposed in a lower portion of the reaction tube. The reaction tube includes a flange formed to protrude outward in the lower portion of the reaction tube, and an extension portion formed to extend downward from a lower end of the flange, the extension portion being formed to have a thickness larger than a thickness of the reaction tube at a position corresponding to the substrate treatment region, and being configured to cover an inner circumferential surface of the furnace opening member. An inner surface of the extension portion protrudes more inward than an inner surface of the reaction tube at the position corresponding to the substrate treatment region.

A film forming apparatus comprises a film forming vessel comprising a first mold and a second mold that is arranged to be opposed to the first mold. The first mold is configured to include a first recessed portion and a first planar portion arranged around the first recessed portion and an exhaust port in a bottom portion of the first recessed portion. The film forming apparatus also comprises a seal member placed between the first planar portion of the first mold and the second mold. The seal member is configured to keep inside of the film forming vessel airtight; and an exhaust device connected with the exhaust port. The work is placed away from the first planar portion such that a film formation target part of the work faces an internal space of the first recessed portion when the film forming vessel is closed. A film forming method comprises (a) forming a film on part of the work by the film forming apparatus; (b) opening the film forming vessel after the (a); and (e) at a start of the (b), evacuating the film forming vessel via the exhaust port by the exhaust device.

A plasma apparatus configured to form a film on or etch a work piece includes: a vacuum chamber including a first casing that has a first recess and a first flat part disposed around the first recess, and a second casing disposed opposite to the first casing; an insulating member that is disposed between the first flat part of the first casing and the second casing, and is configured to contact with the work piece in a state where the work piece faces a space inside the first recess and is separated from the first flat part; and an electricity application unit that is configured to apply electricity to the work piece, wherein a distance between the first flat part and a contact point between the work piece and the insulating member is shorter than a distance between the work piece and a bottom part of the first recess.

A film forming apparatus configured to form a film on part of a work. The film forming apparatus comprises a film forming vessel comprising a first mold located above the work and a second mold located below the work to be opposed to the first mold. The first mold is configured to include a first recessed portion that is recessed upward viewed from a film formation target part of the work and a first planar portion arranged around the first recessed portion. The second mold is configured to include a second planar portion in a place opposed to the first planar portion. The film forming apparatus also comprises a first seal member located between the first planar portion and the work. The first seal member is configured to come into contact with the first planar portion and the work when the work is away from the first planar portion. The film forming apparatus further comprises a second seal member located between the second planar portion and the work. The second seal member is configured to come into contact with the second planar portion and the work when the work is away from the second planar portion. The second seal member is provided on a lower face of the work. This configuration suppresses poor film formation when the seal member is placed between the film forming vessel and the work.