A film deposition device according to the present embodiment includes a chamber. A mounting part is provided in the chamber to allow a substrate to be placed thereon and contains aluminum nitride. A heater is provided in the mounting part. A supply part is configured to supply a process gas for film deposition to the substrate on the mounting part in the chamber. A cover film covers a mounting surface of the mounting part on which the substrate is placed, a back surface opposite to the mounting surface, and a side surface between the mounting surface and the back surface and contains yttrium oxide.

A spray nozzle device according to an embodiment includes a first nozzle having a first spray hole for spraying plasma, a second nozzle spaced apart from the first nozzle and having at least one second spray hole through which the plasma sprayed from the first nozzle passes, a coupling member spaced apart from the second nozzle and coupled to the first nozzle, and at least one connecting member connecting the second nozzle with the coupling member. The second nozzle includes at least one inflow channel for the injection of a deposition material into the second spray hole.

According to one embodiment, a deposition device includes a stage, a deposition head opposed to the stage, and a chamber accommodating the stage and the deposition head. The deposition head comprises a deposition source heating a material and generating vapor, a nozzle connected to the deposition source to emit the vapor generated by the deposition source, a control plate comprising a sleeve surrounding the nozzle, and a movement mechanism moving the control plate along an extension direction of the sleeve.

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.

Described herein is a technique capable of properly attaching a nozzle to a reaction tube. According to one aspect thereof, there is provided a nozzle installation jig including: a lower plate configured to make contact with a process vessel in a vicinity of a lower end opening of the process vessel in which a nozzle is provided; a frame fixed to the lower plate and extending upward with respect to the lower plate; an upper plate fixed to the frame and provided with a sensor configured to detect a position of the nozzle in the process vessel; and a notification device configured to transmit a notification to an operator according to a detection result of the sensor.

Systems and method for producing graphene on a substrate are described. Certain types of exemplar systems include lateral arrangements of a substrate gas scavenging environment and an annealing environment. Certain other types of exemplar systems include lateral arrangements of a graphene producing environment and a cooling environment, which cools the graphene produced on the substrate. Yet other types of exemplar systems include lateral arrangements of a localized annealing environment, localized graphene producing environment and a localized cooling environment inside the same enclosure.

Certain type of exemplar methods for producing graphene on a substrate include scavenging a first portion of the substrate and preferably, contemporaneously annealing a second portion of the substrate. Certain other type of exemplar methods for producing graphene include novel annealing techniques and/or implementing temperature profiles and gas flow rate profiles that vary as a function of lateral distance and/or cooling graphene after producing it.

A substrate processing apparatus includes: a processing container; an injector provided inside the processing container and having a shape extending in a longitudinal direction along which a processing gas is supplied; a holder fixed to the injector; a first magnet fixed to the holder and disposed inside the processing container; a second magnet separated from the first magnet by a partition plate and disposed outside the processing container; and a driving part configured to rotate the second magnet, wherein the first magnet and the second magnet are magnetically coupled to each other, and wherein by rotating the second magnet by the driving part, the first magnet magnetically coupled to the second magnet is rotated, and the injector rotates about the longitudinal direction as an axis.

Embodiments described herein generally relate to a processing system and a method of delivering a reactant gas. The processing system includes a substrate support system, an injection cone, and an intake. The injection cone includes a linear rudder. The linear rudder is disposed such that the flow of reactant gas through the injection cone results in film growth on a specific portion of a substrate. The method includes flowing the gas through the injection cone and delivering the gas onto the substrate below. The localization of the reactant gas, allows for film growth on a specific portion of the substrate.

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 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.