A cleaning solution production system is for cleaning a semiconductor substrate. The system includes a pressure tank, a plasma reaction tank configured to form a plasma in gas bubbles suspended in a decompressed liquid obtained from the pressure tank to thereby generate radical species in the decompressed liquid, a storage tank configured to store a cleaning solution containing the radical species generated in the plasma reaction tank, and a nozzle configured to supply the cleaning solution from the storage tank to a semiconductor substrate.

A plasma processing apparatus includes a conductive mounting table, a conductive member, and a first insulating member. The conductive mounting table has a mounting portion on which a substrate is mounted and a stepped portion positioned lower than the mounting portion. The conductive member is disposed on the stepped portion and extends outward over an outer periphery of the mounting table. Further, a first insulating member is disposed on or above an upper surface of the conductive member.

Systems and methods for plasma processing are disclosed. An exemplary system may include a plasma processing chamber comprising a source to produce a plasma in the processing chamber and at least two bias electrodes arranged within the plasma processing chamber to control plasma sheaths proximate to the bias electrodes. A chuck is disposed to support a substrate, and a source generator is coupled to the plasma electrode. At least one bias supply is coupled to the at least two bias electrodes, and a controller is included to control the at least one bias supply to control the plasma sheaths proximate to the bias electrodes.

A coating apparatus for coating a plurality of substrates includes a chamber body having a reaction chamber, a monomer discharge source having a discharge inlet for introducing a coating forming material into the reaction chamber of the chamber body, and a plasma generation source disposed at a central area of the reaction chamber of the chamber body for exciting the coating forming material, wherein the plurality of substrates is adapted for being arranged around the plasma generation source within the chamber body, so that the uniformity of the coatings formed on the surfaces of the substrates is enhanced, and the deposition velocity is increased.

Exemplary semiconductor processing chamber showerheads may include a dielectric plate characterized by a first surface and a second surface opposite the first surface. The dielectric plate may define a plurality of apertures through the dielectric plate. The dielectric plate may define a first annular channel in the first surface of the dielectric plate, and the first annular channel may extend about the plurality of apertures. The dielectric plate may define a second annular channel in the first surface of the dielectric plate. The second annular channel may be formed radially outward from the first annular channel. The showerheads may also include a conductive material embedded within the dielectric plate and extending about the plurality of apertures without being exposed by the apertures. The conductive material may be exposed at the second annular channel.

Disclosed is a plasma processing method for processing a workpiece that includes: a silicon-containing etching target layer, an organic film provided on the etching target layer, an antireflective film provided on the organic layer, and a first mask provided on the antireflective layer, using a plasma processing apparatus having a processing container. The plasma processing method includes: etching the antireflective film using plasma generated in the processing container and the first mask to form a second mask from the antireflective film; etching the organic film using plasma generated in the processing container and the second mask to form a third mask from the organic film; generating plasma of a mixed gas including the first gas and the second gas in the processing container; and etching the etching target layer using plasma generated in the processing container and the third mask.

The present invention relates generally to a plasma source utilizing a macro-particle reduction coating and method of using a plasma source utilizing a macro-particle reduction for deposition of thin film coatings and modification of surfaces. More particularly, the present invention relates to a plasma source comprising one or more plasma-generating electrodes, wherein a macro-particle reduction coating is deposited on at least a portion of the plasma-generating surfaces of the one or more electrodes to shield the plasma-generating surfaces of the electrodes from erosion by the produced plasma and to resist the formation of particulate matter, thus enhancing the performance and extending the service life of the plasma source.

Embodiments of the invention generally relate to an anode for a semiconductor processing chamber. More specifically, embodiments described herein relate to a process kit including a shield serving as an anode in a physical deposition chamber. The shield has a cylindrical band, the cylindrical band having a top and a bottom, the cylindrical band sized to encircle a sputtering surface of a sputtering target disposed adjacent the top and a substrate support disposed at the bottom, the cylindrical band having an interior surface. A texture is disposed on the interior surface. The texture has a plurality of features. A shaded area is disposed in the feature wherein the shaded area is not visible to the sputtering target. A small anode surface is disposed in the shaded area.

In an active gas generation apparatus of the present invention, an auxiliary conductive film provided on a first electrode dielectric film is provided to overlap part of an active gas flow path in plan view, and the auxiliary conductive film is set to the ground potential. An active gas auxiliary member provided on a second electrode dielectric film is provided to fill part of the active gas flow path between a discharge space and a gas ejection hole in a dielectric space between the first and second electrode dielectric films in order to limit to an active gas flow gap.

An arc chamber has a liner operably coupled to body. The liner has a second surface recessed from a first surface and a hole having a first diameter. The liner has a liner lip extending upwardly from the second surface toward the first surface that surrounds the hole and has a second diameter. An electrode has a shaft and head. The shaft has a third diameter that is less than the first diameter and passes through the body and hole and is electrically isolated from the liner by an annular gap. The head has a fourth diameter and a third surface having an electrode lip extending downwardly from the third surface toward the second surface. The electrode lip has a fifth diameter that is between the second and fourth diameters. A spacing between the liner lip and electrode lip defines a labyrinth seal and generally prevents contaminants from entering the annular gap. The shaft has an annular groove configured to accept a boron nitride seal.