In a plasma processing apparatus, a controller controls one or both of a first high frequency power supply and a second high frequency power supply to periodically stop the supply of one or both of the first high frequency power and the second high frequency power. The controller also controls a switching unit to apply a DC voltage to a focus ring from a first time after a predetermined period of time in which a self-bias voltage of a lower electrode is decreased from a start point of each period in which one or both of the first high frequency power and the second high frequency power are supplied and to stop the application of the DC voltage to the focus ring during each period in which the supply of one or both of the first high frequency power and the second high frequency power is stopped.

A system for performing a bevel cleaning process on a substrate includes a substrate support including an electrode and a plurality of plasma needles arranged around a perimeter of the substrate support. The plasma needles are in fluid communication with a gas delivery system and are configured to supply reactive gases from the gas delivery system to a bevel region of the substrate when the substrate is arranged on the substrate support and electrically couple to the electrode of the substrate support and generate plasma around the bevel region of the substrate.

An apparatus for treating a substrate includes a housing including an open top and a treatment space therein, a gas supply unit configured to supply gas to the treatment space, a support unit including a chuck configured to support the substrate in the treatment space and an upper electrode provided to surround the check when viewed from the top, a dielectric plate unit including a dielectric plate arranged to oppose the substrate supported by the support unit in the treatment space, an upper electrode unit coupled to the dielectric plate unit and including an upper electrode arranged to oppose the lower electrode, and an aligning unit configured to align a horizontal arrangement of the dielectric plate unit, in which a lid extending from the housing in the horizontal direction and coupled to the upper electrode unit is provided on the housing, and the aligning unit is coupled to the lid.

A method for performing a process on a target in a chamber. A gas discharge unit includes a first space having a discharge hole for discharging a first gas, a second space having a discharge hole for discharging a second gas and a third space having a discharge hole for discharging a gas generated between the first and second spaces. A distribution unit includes a first distribution pipe communicating with the first space, a second distribution pipe communicating with the second space and a third distribution pipe communicating with the third space. A valve group includes a first valve opened or closed to the first distribution pipe and a second valve opened or closed to the second distribution pipe. The method includes switching, without mixing the first gas and the second gas, the gas discharged from the discharge hole in the third space by opening or closing the valve group.

Implementations of the present disclosure generally relate to an apparatus for reducing particle contamination on substrates in a plasma processing chamber. The apparatus for reduced particle contamination includes a chamber body, a lid coupled to the chamber body. The chamber body and the lid define a processing volume therebetween. The apparatus also includes a substrate support disposed in the processing volume and an edge ring. The edge ring includes an inner lip disposed over a substrate, a top surface connected to the inner lip, a bottom surface opposite the top surface and extending radially outward from the substrate support, and an inner step between the bottom surface and the inner lip. To avoid depositing the particles on the substrate being processed when the plasma is de-energized, the edge ring shifts the high plasma density zone away from the edge area of the substrate.

There is provided a focus ring that is capable of preventing deposits from adhering to a member having a lower temperature in a gap between two members having different temperatures. A focus ring 25 is disposed to surround a peripheral portion of a wafer W in a chamber 11 of a substrate processing apparatus 10. The focus ring 25 includes an inner focus ring 25a and an outer focus ring 25b. Here, the inner focus ring 25a is placed adjacent to the wafer W and configured to be cooled; and the outer focus ring 25b is placed so as to surround the inner focus ring 25a and configured not to be cooled. Further, a block member 25c is provided in a gap between the inner focus ring 25a and the outer focus ring 25b.

Systems and methods for edge exclusion control are described. One of the systems includes a plasma chamber. The plasma processing chamber includes a lower electrode having a surface for supporting a substrate. The lower electrode is coupled with a radio frequency (RF) power supply. The plasma processing chamber further includes an upper electrode disposed over the lower electrode. The upper electrode is electrically grounded. The plasma processing chamber includes an upper dielectric ring surrounding the upper electrode. The upper dielectric ring is moved using a mechanism for setting a vertical position of the upper dielectric ring separate from a position of the upper electrode. The system further includes an upper electrode extension surrounding the upper dielectric ring. The upper electrode extension is electrically grounded. The system also includes a lower electrode extension surrounding the lower dielectric ring. The lower electrode extension is arranged opposite the upper electrode extension.

A system for controlling of wafer bow in plasma processing stations is described. The system includes a circuit that provides a low frequency RF signal and another circuit that provides a high frequency RF signal. The system includes an output circuit and the stations. The output circuit combines the low frequency RF signal and the high frequency RF signal to generate a plurality of combined RF signals for the stations. Amount of low frequency power delivered to one of the stations depends on wafer bow, such as non-flatness of a wafer. A bowed wafer decreases low frequency power delivered to the station in a multi-station chamber with a common RF source. A shunt inductor is coupled in parallel to each of the stations to increase an amount of current to the station with a bowed wafer. Hence, station power becomes less sensitive to wafer bow to minimize wafer bowing.

Systems and methods for achieving a pre-determined factor associated with the edge region within the plasma chamber is described. One of the methods includes providing an RF signal to a main electrode within the plasma chamber. The RF signal is generated based on a frequency of operation of a first RF generator. The method further includes providing another RF signal to an edge electrode within the plasma chamber. The other RF signal is generated based on the frequency of operation of the first RF generator. The method includes receiving a first measurement of a variable, receiving a second measurement of the variable, and modifying a phase of the other RF signal based on the first measurement and the second measurement. The method includes changing a magnitude of a variable associated with a second RF generator to achieve the pre-determined factor.

A system for performing a bevel cleaning process on a substrate includes a substrate support including an electrode and a plurality of plasma needles arranged around a perimeter of the substrate support. The plasma needles are in fluid communication with a gas delivery system and are configured to supply reactive gases from the gas delivery system to a bevel region of the substrate when the substrate is arranged on the substrate support and electrically couple to the electrode of the substrate support and generate plasma around the bevel region of the substrate.