In some embodiments, a method for cleaning a processing chamber is provided. The method may be performed by introducing a processing gas into a processing chamber that has a by-product disposed along sidewalls of the processing chamber. A plasma is generated from the processing gas using a radio frequency signal. A lower electrode is connected to a first electric potential. Concurrently, a bias voltage having a second electric potential is applied to a sidewall electrode to induce ion bombardment of the by-product, in which the second electric potential has a larger magnitude than the first electric potential. The processing gas is evacuated from the processing chamber.

A method of attracting an object to a mounting table is provided. The object is a substrate, an edge ring, or a combination of the substrate and the edge ring. The mounting table is provided with an electrostatic chuck including electrodes. After the object is placed on the electrostatic chuck, n-phase alternating current (AC) voltages (n≥2) are applied to the electrodes. Each phase voltage of the n-phase AC voltages has a phase different from each other, and the phase voltage of the n-phase AC voltages is applied based on a self-bias voltage of the object.

A plasma processing apparatus includes a balun having a first unbalanced terminal, a second unbalanced terminal, a first balanced terminal, and a second balanced terminal, a grounded vacuum container, a first electrode electrically connected to the first balanced terminal, a second electrode electrically connected to the second balanced terminal, and a ground electrode arranged in the vacuum container and grounded.

Systems and methods for multi-level pulsing of a parameter and multi-level pulsing of a frequency of a radio frequency (RF) signal are described. The parameter is pulsed from a low level to a high level while the frequency is pulsed from a low level to a high level. The parameter and the frequency are simultaneously pulsed to increase a rate of processing a wafer, to increase mask selectivity, and to reduce angular spread of ions within a plasma chamber.

A separated gas inlet structure for blocking plasma backflow includes a gas inlet flange and an upper gas inlet nozzle and a lower gas inlet nozzle made of ceramic materials. The upper gas inlet nozzle is coaxially nested or stacked at the top of the lower gas inlet nozzle; a broken line type gas inlet channel is in the upper gas inlet nozzle and the lower gas inlet nozzle and the gas inlet channel includes an upper axial channel, a radial channel, a lower axial channel and a gas outlet; the radial channel or the lower axial channel is at a mounting matching part of the upper gas inlet nozzle and the lower gas inlet nozzle; and the top of the lower axial channel points to a bottom wall surface of the upper gas inlet nozzle.

This plasma processing apparatus for performing plasma processing on an end part of a substrate includes a processing container, a substrate supporting member configured to support a portion of the substrate and to which a high frequency power is applied, at least a side of the substrate supporting member being composed of a dielectric, an opposing dielectric member composed of a dielectric and disposed to oppose the substrate supporting member, and a gas supply configured to supply a processing gas for generating plasma on at least the end part of the substrate. The plasma processing apparatus further includes a side ground electrode provided at a side of the substrate so as to be close to the substrate to such an extent that an electrical coupling is formed between an end surface of the substrate and the side ground electrode, the side ground electrode having a ground potential.

The present technology encompasses plasma sources including a first plate defining a first plurality of apertures arranged in a first set of rows. The first plate may include a first set of electrodes extending along a separate row of the first set of rows. The plasma sources may include a second plate defining a second plurality of apertures arranged in a second set of rows. The second plate may include a second set of electrodes extending along a separate row of the second set of rows. Each aperture of the second plurality of apertures may be axially aligned with an aperture of the first plurality of apertures. The plasma sources may include a third plate positioned between the first plate and the second plate. The third plate may define a third plurality of apertures.

A controller includes an accumulation determiner configured to determine a first accumulation value that indicates an amount of accumulation of material on surfaces within a processing chamber and a pressure controller configured to obtain the first accumulation value, obtain at least one of a setpoint pressure an etching step and a duration of the etching step, and, to control the pressure within the processing chamber during the etching step, adjust a control parameter based on (i) the first accumulation value and (ii) the at least one of the setpoint pressure and the duration of the etching step.

A method for processing a workpiece, a plasma processing apparatus and a semiconductor device are provided. The method includes placing a workpiece including a spacer layer on a workpiece support in a chamber; selecting a composition modulation gas to modulate a volume ratio of carbon and fluorine to process the workpiece, the composition modulation gas includes one or more molecules, the volume ratio of carbon and fluorine is indicative of a distribution of carbon-based polymer deposited on the spacer layer; generating one or more species using one or more plasmas from a process gas to create a mixture, the process gas includes an etching gas and the composition modulation gas; and exposing the workpiece to the mixture to form a polymer layer on at least a portion of the spacer layer and to etch at least a portion of the spacer layer.

An assembly provided with a coolant flow channel includes a base in which the coolant flow channel is formed; and a protrusion component that is disposed in the coolant flow channel, wherein the protrusion component is liftable or rotatable.