A method of forming a silicon nitride film on a substrate having a recess pattern formed in a surface thereof, includes: forming the silicon nitride film in conformity to the surface of the substrate by supplying each of a raw material gas containing silicon and a nitriding gas for nitriding the raw material gas into a processing container in which the substrate is accommodated; shrinking the silicon nitride film such that a thickness thereof is reduced from a bottom side toward an upper side of the recess pattern by supplying a plasmarized shaping gas for shaping the silicon nitride film to the substrate in a state where the supply of the raw material gas containing silicon into the processing container is stopped; and burying the silicon nitride film in the recess pattern by alternately and repeatedly performing the forming the silicon nitride film and the shrinking the silicon nitride film.

A control apparatus is included in a film forming apparatus that includes: a rotation table disposed in a vacuum container and configured to rotate around a central shaft of a table surface, thereby revolving a substrate on a disposing surface provided on a part of the table surface; a stage configured to rotate around the central shaft of the disposing surface, thereby rotating the substrate on the disposing surface; and a gas supply unit configured to supply a gas into the vacuum container. The control apparatus includes: a display control unit configured to display a setting screen for setting a first parameter that controls a rotation of the substrate; and a process execution unit configured to form a film on the substrate while controlling the rotation of the substrate based on the set first parameter.

A film forming method includes: rotating a rotary table to revolve a substrate which is placed on the rotary table and has a recess in its surface; supplying a raw material gas to a first region on the rotary table; supplying an ammonia gas to a second region on the rotary table; forming a first SiN film in the recess by supplying the raw material gas to the first region and supplying the ammonia gas to the second region at a first flow rate, while the rotary table rotates at a first rotation speed; and forming a second SiN film in the recess such that the second SiN film is laminated on the first SiN film by supplying the raw material gas to the first region and supplying the ammonia gas to the second region at a second flow rate, while the rotary table rotates at a second rotation speed.

In an embodiment, an apparatus includes: a susceptor including substrate pockets; a gas injector disposed over the susceptor, the gas injector having first process regions, the gas injector including a first gas mixing hub and first distribution valves connecting the first gas mixing hub to the first process regions; and a controller connected to the gas injector and the susceptor, the controller being configured to: connect a first precursor material and a carrier gas to the first gas mixing hub; mix the first precursor material and the carrier gas in the first gas mixing hub to produce a first precursor gas; rotate the susceptor to rotate a first substrate disposed in one of the substrate pockets; and while rotating the susceptor, control the first distribution valves to sequentially introduce the first precursor gas at each of the first process regions as the first substrate enters each first process region.

The present disclosure relates to an atomic layer deposition apparatus, and more particularly, to an atomic layer deposition apparatus for depositing an atomic layer on a flexible substrate.

The roll-to-roll atomic layer deposition apparatus according to the embodiment of the present disclosure includes: a casing for providing an inner space that maintains a sealed state; a substrate transfer assembly which is provided in the inner space of the casing and includes a plurality of roll units; and a gas supply assembly for depositing an atomic layer on one surface and a rear surface of a flexible substrate transferred by the substrate transfer assembly, wherein the gas supply assembly includes an upper gas supply module facing the one surface of the substrate, and a lower gas supply module which is spaced apart from the upper gas supply module with the substrate being interposed therebetween and faces the rear surface of the substrate, and the upper gas supply module and the lower gas supply module include at least one purge gas supply unit, at least one reaction gas supply unit, and at least one source gas supply unit that are disposed along the transfer direction of the substrate.

Gas injector inserts having a wedge-shaped housing, at least one first slot and at least one second slot are described. The housing has a first opening in the back face that is in fluid communication with the first slot in the front face and a second opening in the back face that is in fluid communication with the second slot in the front face. Each of the first slot and the second slot has an elongate axis that extends from the inner peripheral end to the outer peripheral end of the housing. The gas injector insert is configured to provide a flow of gas through the first slots at supersonic velocity. Gas distribution assemblies and processing chambers including the gas injector inserts are described.

A deposition apparatus and method of deposition are provided. The deposition apparatus includes a gas supply unit, including: a first process gas supply unit blowing a first process gas onto a deposition-target surface; a second process gas supply unit blowing a second process gas different from the first process gas onto the deposition-target surface of the substrate; and air curtain units blocking an area between an area where the process gas is blown and an area where the second process gas is blown, by blowing an inert gas.

An apparatus for forming a thin film by repeating, plural times, a cycle including supplying and adsorbing a precursor gas onto a substrate and generating a reaction product by allowing the precursor gas on the substrate to react with a reaction gas, which includes: a main precursor gas supply part for supplying the precursor gas; a reaction gas supply part for supplying the reaction gas; an adjustment-purpose precursor gas supply part for supplying an adjustment-purpose precursor gas to adjust an in-plane film thickness distribution of the thin film; and a controller for outputting a control signal to execute a step of forming the thin film using the main precursor gas supply part and the reaction gas supply part, and subsequently a step of supplying the adjustment-purpose precursor gas from the adjustment-purpose precursor gas supply part to compensate for a film thickness of a portion having a relatively thin film thickness.

A spatial atomic layer deposition apparatus that includes a depositor head having an active surface configured to discharge a flow of a first precursor gas, a flow of a second precursor gas, and a flow of an inert gas that separates the flow of the first precursor gas and the flow of the second precursor gas, a substrate plate that opposes the depositor head and has a support surface for retaining a build substrate, a plurality of gap detection sensors producing an output signal indicative of a distance between the active surface of the depositor head and the support surface of the substrate plate, and a controller that communicates with the plurality of gap detection sensors. The gap detection sensors permit a spatial orientation of the active surface of the depositor head and the support surface of the substrate plate to be determined in real-time and monitored.

A powder coating device includes a reaction device, a driving device, a gas supply device, and a gas delivery device. The gas delivery device includes a rotating shaft and a sleeve. The rotating shaft is connected to an inner cylinder and the driving device, and a first gas path communicated with a reaction chamber is defined along an axis of the rotating shaft, and a plurality of gas holes for communicating the first gas path with outside of the rotating shaft are defined in the rotating shaft. The sleeve is sleeved on the rotating shaft, and a second gas path for the rotating shaft to pass through is defined in the sleeve, the second gas path is communicated with the gas supply device, and the plurality of the gas holes is located inside the second gas path.