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.

Systems and methods for plasma processing are disclosed. An exemplary system may include a plasma processing chamber including 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.

According to a method of controlling uniformity of plasma, a first RF driving pulse signal including first RF pulses is generated by pulsing a first RF signal having a first frequency, and a second RF driving pulse signal including second RF pulses is generated by pulsing a second RF signal having a second, lower frequency. The first and second RF driving signals are applied to a top electrode and/or a bottom electrode of a plasma chamber. A harmonic control signal including harmonic control pulses is generated based on timing of the first and second RF pulses. A harmonic component of the first and second RF driving pulse signals is reduced via intermittent activation and deactivation of a harmonic control circuit as controlled by the harmonic control signal. The uniformity of plasma is improved through the control based on timings of the RF driving pulses.

Disclosed are a gas showerhead, a method of manufacturing the same, and a plasma apparatus provided with the gas showerhead. The gas showerhead comprises a back plate and a gas distribution plate, the gas distribution plate including a plurality of annular gas distribution regions with the center of the gas distribution plate as their center; on each annular gas distribution region are provided a plurality of gas through-holes penetrating through the gas inlet face and the gas outlet face, the gas through-holes at least including a plurality of first gas through-holes inclined at a certain angle, and the gas through-holes further include a plurality of second gas through-holes, the second gas through-holes being parallel to the central axis or having a radial inclination direction different from the first gas through-holes; and in the same annular gas distribution region, gas flowing out of the first gas through-holes and gas flowing out of the second gas through-holes are kept away from each other.

Provided is a technique capable of suppressing pressure fluctuations within a plasma processing chamber. A plasma processing apparatus according to the present disclosure includes: a chamber; a gas supply that supplies a processing gas into the chamber; a power supply that generates a source RF signal to form a plasma from the processing gas within the chamber; a storage that stores in advance a source set value that is a set value of a parameter of the source RF signal; a pressure regulation valve connected to the chamber, the pressure regulation valve being configured to regulate an internal pressure of the chamber; an opening degree calculator that calculates an opening degree of the pressure regulation valve, the opening degree being calculated based on the source set value; and an opening degree controller that controls the opening degree of the pressure regulation valve based on the calculated opening degree.

The disclosed plasma processing apparatus is provided with a chamber, a substrate support, and a power source system. The substrate support has an electrode and configured to support a substrate in the chamber. The power source system is electrically connected to the electrode and configured to apply a bias voltage to the electrode to draw ions from a plasma in the chamber into the substrate on the substrate support. The power source system is configured to output a first pulse to the electrode in a first period and output a second pulse to the electrode in a second period after the first period, as the bias voltage. Each of the first pulse and the second pulse is a pulse of a voltage. A voltage level of the first pulse is different from a voltage level of the second pulse.

Apparatus and methods to control the phase of power sources for plasma process regions in a batch process chamber. A master exciter controls the phase of the power sources during the process sequence based on feedback from the match circuits of the respective plasma sources.

A method of forming a film stack with reduced defects is provided and includes positioning a substrate on a substrate support within a processing chamber and sequentially depositing polysilicon layers and silicon oxide layers to produce the film stack on the substrate. The method also includes supplying a current of greater than 5 ampere (A) to a plasma profile modulator while generating a deposition plasma within the processing chamber, exposing the substrate to the deposition plasma while depositing the polysilicon layers and the silicon oxide layers, and maintaining the processing chamber at a pressure of greater than 2 Torr to about 100 Torr while depositing the polysilicon layers and the silicon oxide layers.

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.

In one embodiment, an RF impedance matching network for a plasma chamber is disclosed. The matching network includes a mechanically variable capacitor (MVC) and a second variable capacitor. A control circuit is configured to carry out a first process for altering the second variable capacitor and the RF source frequency to reduce reflected power. The control circuit is further configured to carry out a second process of, upon determining that the alteration of the RF source frequency has caused the RF source frequency to be outside, at a minimum, or at a maximum of a predetermined frequency range, determining a new MVC configuration to cause the RF source frequency, according to the first process, to be altered to be within or closer to the predetermined frequency range. The new MVC configuration is based on the RF source frequency and the predetermined frequency range.