Disclosed are a plasma processing device and a retractable sealing part thereof. The retractable sealing part is arranged in or near a radio-frequency circuit of the plasma processing device. The retractable sealing part includes a bellows assembly having a first end and a second end. Isolation rings are added to an upper part and a lower part of the bellows assembly to weaken longitudinal radio-frequency coupling. Metal sleeves are added to an inner side and an outer side of the bellows assembly to shield transverse radio-frequency coupling. The present disclosure effectively shields radio-frequency coupling on the basis of maintaining the functions of vacuum isolation and extension and retraction of the retractable sealing part, thereby obtaining the stable radio-frequency circuit and etching rate.

Radio frequency power conveyed to individual process stations of a multi-station integrated circuit fabrication chamber may be adjusted so as to bring the rates at which fabrication processes occur, and/or fabrication process results, into alignment with one another. Such adjustment in radio frequency power, which may be accomplished via adjusting one or more reactive elements of a RF distribution network, may give rise to an imbalance in power delivered to each individual process station.

A high-frequency power circuit includes a first antenna circuit and a second antenna circuit that are connected in parallel to a matching box connected to a high-frequency power supply. The first antenna circuit include a first antenna, a first distribution capacitor, and a first variable capacitor. The second antenna circuit includes a second antenna, a second distribution capacitor, and a second variable capacitor. A controller sets a capacitance of the first variable capacitor based on a detection result of a phase difference between current and voltage in a series-connected portion of the first antenna and the first variable capacitor during plasma production to reduce this phase difference and sets a capacitance of the second variable capacitor based on a detection result of a phase difference between current and voltage in a series-connected portion of the second antenna and the second variable capacitor during plasma production to reduce this phase difference.

Systems, devices, and methods are discussed relating to plasma sources using load current switch timing of zero volt switching resonant topology.

An apparatus for plasma processing is configured to generate plasma in a chamber and periodically apply a pulsed negative DC voltage to an upper electrode from a DC power supply in the plasma processing on a substrate and in plasma cleaning. A duty ratio of the pulsed negative DC voltage used for the plasma processing is smaller than a duty ratio of the pulsed negative DC voltage used for the plasma cleaning. An absolute value of an average value of an output voltage of the DC power supply used for the plasma processing is smaller than an absolute value of an average value of the output voltage of the DC power supply used for the plasma cleaning.

Embodiments described herein are applicable for use in all types of plasma assisted or plasma enhanced processing chambers and also for methods of plasma assisted or plasma enhanced processing of a substrate. More specifically, embodiments of this disclosure include a broadband filter assembly, also referred to herein as a filter assembly, that is configured to reduce and/or prevent RF leakage currents from being transferred from one or more RF driven components to a ground through other electrical components that are directly or indirectly electrically coupled to the RF driven components and ground with high input impedance (low current loss) making it compatible with shaped DC pulse bias applications.

A plasma processing apparatus includes a stage for supporting a target object in a chamber defined by a chamber body. The stage includes a lower electrode, an electrostatic chuck provided on the lower electrode, heaters provided in the electrostatic chuck, and terminals electrically connected to the heaters. A conductor pipe electrically connects a high frequency power supply and the lower electrode and extends from the lower electrode to the outside of the chamber body. Power supply lines supply power from a heater controller to the heaters. Filters partially forming the power supply lines prevent the inflow of high frequency power from the heaters to the heater controller. The power supply lines include wirings which respectively connect the terminals and the filters and extend to the outside of the chamber body through an inner bore of the conductor pipe.

A tunable edge sheath (TES) system includes a coupling ring configured to couple to a bottom surface of an edge ring that surrounds a wafer support area within a plasma processing chamber. The TES system includes an annular-shaped electrode embedded within the coupling ring. The TES system includes a plurality of radiofrequency signal supply pins coupled to the electrode within the coupling ring. Each of the plurality of radiofrequency signal supply pins extends through a corresponding hole formed through a bottom surface of the coupling ring. The TES system includes a plurality of radiofrequency signal filters respectively connected to the plurality of radiofrequency supply pins. Each of the plurality of radiofrequency signal filters is configured to provide a high impedance to radiofrequency signals used to generate a plasma within the plasma processing chamber.

A plasma processing apparatus comprising: a plasma processing chamber; a substrate support disposed in the plasma processing chamber, and including a lower electrode, an electrostatic chuck, and an edge ring disposed to surround a substrate mounted on the electrostatic chuck; a driving device; an upper electrode disposed above the substrate support. In an example, the apparatus further comprises a source RF power supply; a bias RF power supply configured to supply bias RF power to the lower electrode; at least one conductor; a DC power supply; an RF filter electrically; and a controller configured to control the driving device and the at least one variable passive element, and adjust an incident angle of an ion in the plasma with respect to an edge area of the substrate mounted on the electrostatic chuck.

The present invention relates to a method of forming a coating layer having plasma resistance, the method comprising steps of: preparing a substrate by placing the substrate in a substrate fixing device inside a process chamber; evaporating a Y.sub.2O.sub.3 deposition material provided in a solid form in an electron beam source by irradiating an electron beam on the Y.sub.2O.sub.3 deposition material; generating radical particles having activation energy by injecting a process gas containing oxygen for forming radicals into a RF energy beam source; irradiating an RF energy beam including the radical particles generated in the RF energy beam source, toward the substrate; depositing a thin film in which the evaporated deposition material is deposited on the substrate by being assisted by the RF energy beam, and densifying the thin film in which the deposition material deposited on the substrate forms a densified film by ion bombardment of the RF energy beam.