In one example, a flow module. The flow module has an inner wall and an outer wall equal-distant from the central axis. The flow module has radial walls connected between the outer wall and the inner wall, wherein the outer wall, inner wall and two or more pairs of radial walls define evacuation channels and a center portion. The center portion and evacuation channels are fluidly isolated from each other in the flow module. Two or more through holes are formed through the outer wall and fluidly coupled to the center portion. At least two of the two or more through holes are 180 degrees apart and linearly aligned through the central axis.

A plasma processing apparatus includes: a chamber; an introducer installed such that electromagnetic waves are introduced into the chamber from the introducer; and a choke structure installed on a wall of the chamber and configured to suppress propagation of the electromagnetic waves downstream along an inner wall surface of the chamber from a location at which the choke structure is installed. The choke structure includes: a first portion having a slit shape and connected to a space within the chamber; and a second portion extending from the first portion in the wall of the chamber. A length of the second portion along a direction of an electric field of the electromagnetic waves in the second portion is longer than a length of the first portion along a direction of an electric field of the electromagnetic waves in the first portion.

A plasma processing apparatus for cleaning a peripheral portion of a substrate by plasma and comprising a depressurizable processing container accommodating a substrate is disclosed. The processing container includes a substrate support for supporting a substrate and including a central electrode facing a central portion of the supported substrate supported by the substrate support; a lower ring electrode formed in a ring shape to face a lower surface of a peripheral portion of the substrate supported by the substrate support; and an upper ring electrode disposed to face an upper surface of the peripheral portion of the substrate supported by the substrate support. The central electrode is grounded, a radio frequency (RF) power is supplied to each of the upper and lower ring electrodes, and the RF power is supplied to at least one of the upper and lower ring electrodes via a phase adjuster configured to adjust the phase of the RF power.

A plasma processing system includes a chamber, a gas supply unit, a gas exhaust unit, a separating unit, a boost unit and an accumulation unit. The chamber is configured to process a target substrate by plasma of a gaseous mixture of a rare gas and a processing gas. The gas supply unit is configured to supply the rare gas and the processing gas into the chamber. The gas exhaust unit is configured to exhaust a gas containing the rare gas from the chamber. The separating unit is configured to separate the rare gas from the gas exhausted by the gas exhaust unit. The boost unit is configured to boost the rare gas separated by the separating unit. The accumulation unit is configured to accumulate the rare gas boosted by the boost unit and supply the accumulated first rare gas to the gas supply unit.

A purge baffle for a substrate support includes an annular ring configured to surround an outer perimeter around the substrate support in a volume below the substrate support and a first portion. The first portion includes a plenum defined below the first portion and outside of the annular ring in the volume below the substrate support and a plurality of openings that provide respective flow paths from a region above the first portion into the plenum. At least a first opening of the plurality of openings has a first conductance and at least a second opening of the plurality of openings has a second conductance that is different than the first conductance.

A machine and a wafer processing apparatus are provided; the machine includes a body and an adjustment part. The body is configured to bear a wafer; the adjustment part is disposed in the body, and the adjustment part uses a vacuum suction to adjust a levelness of an in-process wafer.

According to one aspect of the technique of the present disclosure, there is provided a substrate processing apparatus including: a process vessel in which a substrate is processed; an outer vessel configured to cover an outer circumference of the process vessel; a gas flow path provided between the outer vessel and the outer circumference of the process vessel; an exhaust path in communication with the gas flow path; an adjusting valve configured to be capable of adjusting a conductance of the exhaust path; a first exhaust apparatus provided on the exhaust path downstream of the adjusting valve; a pressure sensor configured to measure an inner pressure of the outer vessel; and a controller configured to be capable of adjusting an exhaust volume flow rate of the first exhaust apparatus by controlling the first exhaust apparatus based on a pressure measured by the pressure sensor.

Implementations of the present disclosure provide a process kit for an electrostatic chuck. In one implementation, a substrate support assembly is provided. The substrate support assembly includes an electrostatic chuck having a first recess formed in an upper portion of the electrostatic chuck. A process kit surrounds the electrostatic chuck. The process kit includes an inner ring and an outer ring disposed radially outward of the inner ring. The outer ring includes a second recess formed in an upper portion of the upper ring. The inner ring is positioned within and is supported by the first recess and the second recess. An upper surface of the inner ring and an upper surface of the outer ring are co-planar.

According to one aspect of the present invention, a method of treating a substrate within a chamber includes performing a unit cycle at least one time, in which the unit cycle includes a substrate treatment step of supplying a reaction gas in which radicals constituting plasma of a first treatment gas are mixed with a second treatment gas onto the substrate, wherein the substrate includes a first thin film, and a second thin film having a lower reactivity to the reaction gas than the first thin film.

When a gas supplied to a gas injection unit is switched from a first processing gas to a second processing gas, a controller of a gas supply system performs control to open a first supply on/off valve connected to the gas injection unit and provided in a first gas supply line for supplying the first processing gas and a second exhaust on/off valve provided in a first gas exhaust line branched from the first gas supply line, close a second supply on/off valve connected to the gas injection unit and provided in a second gas supply line for supplying the second processing gas and a first exhaust on/off valve provided in a second gas exhaust line branched from the second gas supply line; and then open the second supply on/off valve and the first exhaust on/off valve and close the first supply on/off valve and the second exhaust on/off valve.