A substrate processing apparatus, includes a sealed pressure vessel, such as an Atomic Layer Deposition, ALD, apparatus, a fluid inlet assembly attached to a wall of the sealed pressure vessel, the fluid inlet assembly having a fluid inlet pipe passing through the wall, and a resilient element in the fluid inlet assembly around the fluid inlet pipe coupling the inlet pipe to the wall, where one of an interior surface and an exterior surface of the resilient element sees pressure prevailing within the pressure vessel and the other sees ambient pressure, and where the fluid inlet pipe prevents fluid carried inside from being in contact with the resilient element, and a relating method.

There is provided a technique that includes: (a) arranging a plurality of first substrates and a second substrate having a smaller surface area than the first substrates and accommodating the plurality of first substrates and the second substrate in a process chamber; and (b) forming a thin film on each of the plurality of first substrates by supplying a processing gas to a substrate arrangement region in which the plurality of first substrates and the second substrate are arranged, wherein (b) includes: (c) supplying a dilution gas to a first supply region of the substrate arrangement region, or not performing a supply of the dilution gas to the first supply region, and supplying the dilution gas to at least one second supply region of the substrate arrangement region at a flow rate larger than a flow rate of the dilution gas supplied to the first supply region.

A substrate cleaning method includes: supplying a gas mixture of a cluster forming gas for forming a cluster by adiabatic expansion and a carrier gas having a smaller molecular weight or atomic weight than the cluster forming gas to a nozzle; forming the cluster by injecting the gas mixture from the nozzle; removing particles adhering to the substrate by the cluster; and continuously supplying the carrier gas to the nozzle for a set time period from an end time of the supply of the cluster forming gas to the nozzle.

Systems and techniques for depositing organic material on a substrate are provided, in which one or more shield gas flows prevents contamination of the substrate by the chamber ambient. Thus, multiple layers of the same or different materials may be deposited in a single deposition chamber, without the need for movement between different deposition chambers, and with reduced chance of cross-contamination between layers.

Devices for deposition of material via organic vapor jet printing (OVJP) and similar techniques are provided. The depositor includes delivery channels ending in delivery apertures, where the delivery channels are flared as they approach the delivery apertures, and/or have a trapezoidal shape. The depositors are suitable for fabricating OLEDs and OLED components and similar devices.

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.

According to one aspect of a technique the present disclosure, there is provided a substrate processing apparatus including: a substrate support configured to support a substrate; a reaction tube in which the substrate support is accommodated; a heater provided around the reaction tube; and an accommodation structure provided at a side surface of the reaction tube and configured to accommodate one or both of: a gas supply nozzle provided so as to extend from an outside of the reaction tube toward an inside of the reaction tube in a horizontal direction with respect to a surface of the substrate supported by the substrate support; and a first temperature measuring structure provided so as to extend from the outside of the reaction tube toward the inside of the reaction tube in the horizontal direction with respect to the surface of the substrate supported by the substrate support.

Apparatus and methods for supplying a vapor to a processing chamber such as a film deposition chamber are described. The vapor delivery apparatus comprises an inlet conduit and an outlet conduit, in fluid communication with an ampoule. A needle valve device restricts flow through the outlet conduit.

A technique for connecting a nozzle to a reaction tube while preventing the nozzle from collapsing includes a substrate processing apparatus including: a gas introduction structure comprising a non-metallic material penetrating a side wall of a process vessel and integrated with the side wall as a single structure, wherein a front end thereof protrudes into the process vessel; a nozzle made of a non-metallic material and including: a first straight portion inserted into the gas introduction structure and fluidically communicating with the gas introduction structure; and a second straight portion fluidically communicating with the first straight portion and extending along an inner wall of the process vessel; and a fixing block provided at an inner side of the process vessel and above the gas introduction structure, wherein the fixing block has a groove where the nozzle can be moved in a radial direction of the process vessel.