A plasma system and a filter device are provided. In the system, an area surrounded by a dielectric window is configured as a first chamber for accommodating plasma. A first adapter is arranged under the dielectric window. An area surrounded by the first adapter is configured as a second chamber. A lower electrode platform is placed in the second chamber to carry a workpiece. A filter member of the filter device is placed at an intersection of the first chamber and the second chamber. The filter member includes through-holes configured to filter ions from the plasma. A first extension member extends from the filter member in a first direction and is placed over the first adapter. A second extension member extends from a position of the filter member adjacent to the first extension member to an inner side of the first adapter.

There is provided a substrate processing apparatus that includes a process chamber in which at least one substrate is processed; a gas supplier configured to supply a gas; and a buffer structure. The buffer structure includes at least two plasma generation regions in which gas is converted into plasma by a pair of electrodes connected to a high-frequency power supply and an electrode to be grounded, a first gas supply port that supplies a gas generated in a first plasma generation region among the at least two plasma generation regions, and a second gas supply port that supplies a gas generated in a second plasma generation region among the at least two plasma generation regions.

There is provision of a plasma processing apparatus including a processing vessel, a first member provided in the processing vessel, and a second member provided outside the first member. In at least one of the first member and the second member, a gas flow passage is formed, and the gas flow passage is configured to cause a gas to flow into a gap between the first member and the second member.

A temperature changing method includes changing a pressure of a gas supplied from a gas supply to a gap between the substrate and an electrostatic chuck from a first pressure to a second pressure being lower than the first pressure, changing a voltage applied to the electrostatic chuck from a first voltage to a second voltage being lower than the first voltage, changing a temperature of the electrostatic chuck from a first temperature to a second temperature, electrostatically attracting the substrate by the electrostatic chuck for a time in a state where the gas pressure is the second pressure and the voltage is the second voltage, changing the gas pressure from the second pressure to a third pressure being lower than the first pressure and higher than the second pressure, and changing the voltage from the second voltage to a third voltage being higher than the second voltage.

The disclosure describes a plasma source assemblies comprising a differential screw assembly, an RF hot electrode, a top cover, an upper housing and a lower housing. The differential screw assembly is configured to provide force to align the plasma source assembly vertically matching planarity of a susceptor. More particularly, the differential screw assembly increases a distance between the top cover and the upper housing to align the gap with the susceptor. The disclosure also provides a better thermal management by cooling fins. A temperature capacity of the plasma source assemblies is extended by using titanium electrode. The disclosure provides a cladding material covering a portion of a first surface of RF hot electrode, a second surface of RF hot electrode, a bottom surface of RF hot electrode, a portion of a surface of the showerhead and a portion of lower housing surface.

According to one aspect of the technique of the present disclosure, there is provided a method of manufacturing a semiconductor device, including: (A) creating a recipe by setting opening/closing states of a plurality of valves on a gas pattern screen; and (B) processing a substrate by performing the recipe created in (A), wherein (A) includes: (a) selecting a gas pipe on the gas pattern screen when an opening/closing state of any valve among the plurality of valves changes on the gas pattern screen; and (b) confirming opening/closing states of one or more valves connected to the gas pipe selected in (a).

There is provided a substrate processing apparatus including: an inner tube including a substrate accommodating region where substrates are accommodated along an arrangement direction; an outer tube outside the inner tube; gas supply ports provided on a side wall of the inner tube along the arrangement direction; first exhaust ports provided on the side wall of the inner tube along the arrangement direction; a second exhaust port provided at an end portion of the outer tube along the arrangement direction; and a gas guide controlling gas flow in an annular space between the inner and outer tubes. A first exhaust port A is located farthest from the second exhaust port, and faces a gas supply port A. The gas guide includes a fin provided near the gas supply port A and surrounds at least a part of an outer periphery of the gas supply port A.

An electrostatic chuck includes: a disk-shaped ceramic plate having a wafer placement surface on a surface thereof; an electrostatic electrode embedded in the ceramic plate; and gas grooves that are divided in a plurality of zones when the ceramic plate is seen from above and each of which is independently provided in the wafer placement surface so as to extend from one to the other of a pair of gas supply/discharge openings for a corresponding one of the zones. A pattern in which a gas is supplied to each of the gas grooves provided for a corresponding one of the zones is selectable between a first pattern in which the gas flows from one to the other of the pair of gas supply/discharge openings and a second pattern in which the gas flows from the other to the one of the pair of gas supply/discharge openings.

Provided in an active gas generation apparatus according to the present disclosure is a gas separation structure of separating a gas flow between an in-housing space and a discharge space by a cooling plate, an electrode holding member, and a high voltage apply electrode part. The active gas generation apparatus further includes an auxiliary metal electrode provided on an upper surface of an electrode dielectric film in the high voltage apply electrode part. The auxiliary metal electrode is provided to overlap with part of an active gas transmission path in a plan view, and set to ground potential.

The cleaning method according to an embodiment of the present invention is for cleaning a plasma processing apparatus that performs a plasma processing on a substrate. This cleaning method includes: forming a protective film; and cleaning. The forming the protective film involves forming the protective film in a plasma generation region by generating plasma while supplying a film-forming gas into a processing container in which a processing space including the plasma generation region and a diffusion region is formed. The cleaning involves cleaning an interior of the processing container in which the protective film has been formed by generating plasma while supplying a cleaning gas into the processing container.