There is provided is a technique includes: at least one processing chamber in which a substrate is processed; a processing gas supplier that supplies a processing gas to the at least one processing chamber; a transfer chamber communicable with the at least one processing chamber; a first inert gas supplier that supplies an inert gas to the transfer chamber; a first exhauster that discharges an atmosphere from the transfer chamber; and a second inert gas supplier that supplies the inert gas discharged by the first exhauster to the at least one processing chamber or a downstream portion of the at least one processing chamber.

A semiconductor wafer carrier structure includes a carrier body having a surface; a protective film covering the surface; a susceptor disposed on the carrier body; and a patterned coating film on the susceptor, wherein the patterned coating film has two or more different thicknesses, wherein patterns of the patterned coating film are symmetrically distributed with respect to a center of the susceptor.

A semiconductor wafer carrier structure includes a carrier body having a surface; a protective film covering the surface; a susceptor disposed on the carrier body; and a patterned coating film on the susceptor, wherein the patterned coating film has two or more different thicknesses, wherein patterns of the patterned coating film are symmetrically distributed with respect to a center of the susceptor.

A susceptor used in a deposition reactor provides heat input and controls the build-up of errant deposition. The susceptor heats a substrate tape within the reactor upon which one or more thin films are deposited, particularly high temperature superconductor (HTS) thin films produced in a MOCVD reactor.

The present disclosure relates to a substrate processing apparatus and method. The substrate processing apparatus and method can sequentially inject process gases onto substrates located in first and second spaces obtained by dividing the internal space of a chamber in the substrate processing apparatus, thereby forming thin films with uniform thicknesses on the substrates located in the first and second spaces.

The disclosed technology relates generally to semiconductor processing and more particularly to liquid precursor injection apparatus and methods for depositing thin films. A method of injecting a liquid precursor into a thin film deposition chamber comprises delivering a vaporized liquid precursor into the thin film deposition chamber by atomizing the liquid precursor into atomized precursor droplets using a liquid injection unit and vaporizing the atomized precursor droplets into the vaporized liquid precursor in a vaporization chamber. The liquid injector unit and the liquid precursor are such that operating the liquid precursor delivery unit under a lower stability condition, including a first liquid precursor temperature at the liquid injection unit, a first liquid precursor pressure upstream of the liquid precursor injection unit and a first gas pressure downstream of the liquid precursor injection unit, causes a mass flow rate of the liquid precursor to vary by more than 10% relative to an average mass flow rate of the liquid precursor during a first time duration. Delivering the vaporized liquid precursor into the thin film deposition chamber comprises operating the liquid precursor delivery unit under a higher stability condition. The higher stability includes one or more of: a second liquid precursor temperature at the liquid injection unit that is lower than the first liquid temperature; a second liquid pressure upstream of the injection unit that is higher than the first liquid pressure; and a second gas pressure downstream of the liquid injection unit that is higher than the first Gas pressure. The higher stability is such that that the mass flow rate of the liquid precursor varies by less than 10% relative to an average mass flow rate during a second time duration having the same time duration as the first time duration.

The disclosed technology relates generally to semiconductor processing and more particularly to liquid precursor injection apparatus and methods for depositing thin films. A method of injecting a liquid precursor into a thin film deposition chamber comprises delivering a vaporized liquid precursor into the thin film deposition chamber by atomizing the liquid precursor into atomized precursor droplets using a liquid injection unit and vaporizing the atomized precursor droplets into the vaporized liquid precursor in a vaporization chamber. The liquid injector unit and the liquid precursor are such that operating the liquid precursor delivery unit under a lower stability condition, including a first liquid precursor temperature at the liquid injection unit, a first liquid precursor pressure upstream of the liquid precursor injection unit and a first gas pressure downstream of the liquid precursor injection unit, causes a mass flow rate of the liquid precursor to vary by more than 10% relative to an average mass flow rate of the liquid precursor during a first time duration. Delivering the vaporized liquid precursor into the thin film deposition chamber comprises operating the liquid precursor delivery unit under a higher stability condition. The higher stability includes one or more of: a second liquid precursor temperature at the liquid injection unit that is lower than the first liquid temperature; a second liquid pressure upstream of the injection unit that is higher than the first liquid pressure; and a second gas pressure downstream of the liquid injection unit that is higher than the first Gas pressure. The higher stability is such that that the mass flow rate of the liquid precursor varies by less than 10% relative to an average mass flow rate during a second time duration having the same time duration as the first time duration.

An apparatus for coating a PET container in a coating chamber includes a lance that introduces material and energy into the container while it is in the coating chamber. This results in a reaction that coats the bottle's interior with a silicon oxide. Before reaching the coating chamber, the bottle will have passed through a cooling system connected to coating chamber. The cooling system passes cooled gas through a feed, thereby cooling said bottle before it reaches the coating chamber.

An apparatus for coating a PET container in a coating chamber includes a lance that introduces material and energy into the container while it is in the coating chamber. This results in a reaction that coats the bottle's interior with a silicon oxide. Before reaching the coating chamber, the bottle will have passed through a cooling system connected to coating chamber. The cooling system passes cooled gas through a feed, thereby cooling said bottle before it reaches the coating chamber.

A vacuum lock for a vacuum coating plant comprises a chamber for receiving a substrate carrier, wherein the chamber comprises a first and a second inner surface. A conveyor is configured for conveying the substrate carrier. The vacuum lock comprises a flow channel assembly for evacuating and venting the chamber, the flow channel assembly being configured to cause a gas flow between both the first inner surface and a first substrate carrier surface facing the first inner surface and between the second inner surface and a second substrate carrier surface facing the second inner surface. The substrate carrier can be positioned between the first and the second inner surfaces such that a ratio of a first distance between the first inner surface and the first substrate carrier surface to a length (L) of the substrate carrier is smaller than 0.1, and a ratio of a second distance between the second inner surface and the second substrate carrier surface to a length (L) of the substrate carrier is smaller than 0.1.