A plasma processing apparatus includes a chamber; a first electrode facing an inside of the chamber; a radio-frequency power supply configured to supply a radio-frequency power to the first electrode; a feeding rod configured to feed the radio-frequency power to a center of a surface of the first electrode opposite to a surface facing the inside of the chamber; a conductive plate provided in parallel to the surface of the first electrode opposite to the surface facing the inside of the chamber, the plate being grounded; and a dielectric plate connecting the first electrode and the conductive plate, and having a shape that is rotationally symmetric with respect to a center of the first electrode.

A method for processing a substrate includes providing the substrate, a film being formed on the substrate, performing pretreatment to surface-treat the film formed on the substrate using a treatment gas in a plasma state, and performing, after the pretreatment, liquid treatment to remove the film from the substrate by supplying a treatment liquid onto the substrate.

An electrostatic chuck assembly includes an electrostatic chuck including a circular-shaped electrostatic dielectric layer on which a wafer is mounted and an adsorption electrode in the electrostatic dielectric layer, and a control part configured to control the electrostatic chuck, wherein the adsorption electrode comprises a plurality of sub-adsorption electrodes separated from each other in an X direction and a Y direction perpendicular to the X direction on a plane level from a central portion of the electrostatic dielectric layer.

A plasma processing apparatus includes a process container that forms a process space to accommodate a target substrate, and a first electrode and a second electrode disposed opposite each other inside the process container. The first electrode is an upper electrode and the second electrode is a lower electrode and configured to support the target substrate through a mount face. A correction ring is disposed to surround the target substrate placed on the mount face of the second electrode. The correction ring includes a combination of a first ring to be around the target substrate and a second ring arranged around or above the first ring. A power supply unit is configured to apply a first electric potential and a second electric potential respectively to the first ring and the second ring to generate a potential difference between the first and second rings. The power supply unit is configured to variably set the potential difference.

Systems and methods for active control of radial etch uniformity are described. One of the methods includes generating a radio frequency (RF) signal having a fundamental frequency and generating another RF signal having a harmonic frequency. The harmonic frequency, or a phase, or a parameter level, or a combination thereof of the other RF signal are controlled to control harmonics of RF plasma sheath within a plasma chamber to achieve radial etch uniformity.

The present technology includes improved gas distribution designs for forming uniform plasmas during semiconductor processing operations or for treating the interior of semiconductor processing chambers. While conventional gas distribution assemblies may receive a specific reactant or reactant ratio which is then distributed into the plasma region, the presently described technology allows for improved control of the reactant input distribution. The technology allows for separate flows of reactants to different regions of the plasma to offset any irregularities observed in process uniformity. A first precursor may be delivered to the center of the plasma above the center of the substrate/pedestal while a second precursor may be delivered to an outer portion of the plasma above an outer portion of the substrate/pedestal. In so doing, a substrate residing on the pedestal may experience a more uniform etch or deposition profile across the entire surface.

A method of an embodiment includes (i) a step of supplying a first gas to a chamber, wherein the first gas is perfiuorotetraglyme gas, and (ii) a step of generating plasma of a second gas for etching of a porous film in order to etch the porous film at the same time as the step of supplying a first gas or after the step of supplying a first gas. Partial pressure of the first gas in the chamber or pressure of the first gas in the chamber when only the first gas is supplied to the chamber is higher than critical pressure causing capillary condensation of the first gas in the porous film and is lower than saturated vapor pressure of the first gas at a temperature of the workpiece during execution of the step of supplying a first gas.

A plasma processing method includes executing an etching process that includes supplying an etching gas into a process container in which a target substrate is supported on a second electrode serving as a lower electrode, and applying an RF power for plasma generation and an RF power for ion attraction to turn the etching gas into plasma and to subject the target substrate to etching. The etching process includes applying a negative DC voltage to a first electrode serving as an upper electrode during the etching to increase an absolute value of self-bias on the first electrode. The etching process includes releasing DC electron current generated by the negative DC voltage to ground through plasma and a conductive member disposed as a ring around the first electrode, by using a first state where the conductive member is connected to a ground potential portion.

Provided is a separate plasma source coil and a method of controlling the same. The separate plasma source coil includes a center coil group disposed around a coil center and including one or more linear center coils, and an edge coil group disposed around the center coil group and including one or more linear edge coils.

Based on the fact that a film thickness of a film formed in a film formation processing of repeatedly performing a first sequence varies according to a temperature of the surface on which the film is to be formed, the film formation processing is performed after the temperature of each region of the surface of the wafer is adjusted to reduce a deviation of a trench on the surface of the wafer, so that the film is very precisely formed on the inner surface of the trench while reducing the deviation of the trench on the surface of the wafer. When the trench width is narrower than a reference width, an etching processing of repeatedly performing a second sequence is performed in order to expand the trench width, so that the surface of the film provided in the inner surface of the trench is isotropically and uniformly etched.