The present disclosure relates to an electrostatic chuck. The electrostatic chuck according to the present disclosure may include a base substrate; an electrostatic chuck plate fixed on the base substrate, the electrostatic chuck plate having an electrode therein; and an electrode part disposed in a hole in the base substrate to supply power to the electrode, wherein the electrode part may include a housing inserted into the hole in the base substrate, an electrode rod passing through the inner wall of the housing such that one end thereof is in contact with the electrode; and an elastic support body configured to support the electrode rod at multiple points on the inner wall of the housing.

Provided is a plasma processing apparatus capable of obtaining desired etch profiles and preventing the degradation of yield rates due to the adhesion of particles, and equipped with a processing chamber in which a sample is plasma-treated; a radio-frequency power source for supplying radio-frequency power used to generate plasma; a sample stage which is provided with electrodes for electrostatically adsorbing the sample and on which the sample is mounted; and a DC power supply for applying DC voltages to the electrodes, the apparatus being further equipped with a control apparatus for controlling the DC power supply so as to apply such DC voltages as to decrease the absolute value of the potential of the sample in the absence of the plasma.

An isolation system includes an input junction coupled to one or more RF power supplies via a match network for receiving radio frequency (RF) power. The isolation system further includes a plurality of channel paths connected to the input junction for distributing the RF power among the channel paths. The isolation system includes an output junction connected between each of the channel paths and to an electrode of a plasma chamber for receiving portions of the distributed RF power to output combined power and providing the combined RF power to the electrode. Each of the channel paths includes bottom and top capacitors for blocking a signal of the different type than that of the RF power. The isolation system avoids a risk of electrical arcing created by a voltage difference between an RF terminal and a non-RF terminal when the terminals are placed proximate to each other.

Embodiments of the present disclosure generally include an apparatus and methods for measuring and controlling in real-time a potential formed on a substrate in a plasma processing chamber during plasma processing. Embodiments of the disclosure include a plasma processing system that includes a substrate support disposed within a processing volume of the plasma processing system, the substrate support comprising a substrate supporting surface and a dielectric layer disposed between a first electrode and the substrate supporting surface. The plasma processing system further includes a first generator coupled to a second electrode of the plasma processing system, and a sensor disposed a first distance from the substrate supporting surface. The first generator is configured to generate a plasma within the processing volume. The first electrode is disposed a second distance from the substrate supporting surface, and the first distance is less than the second distance. The sensor is generally configured to detect an electric field strength and/or a voltage formed on the substrate during plasma processing.

Plasma processing systems and methods are disclosed. The system may include at least one modulating supply that modulates plasma properties where the modulation of the plasma properties has a repetition period, T. A synchronization module configured to send a synchronization signal with a synchronization-signal-repetition-period that is an integer multiple of T to at least one piece of equipment connected to the plasma processing system. A waveform-communication module communicates characteristics of a characterized waveform to at least one piece of equipment connected to the plasma system to enable synchronization of pieces of equipment connected to the plasma processing system. The characterized waveform may contain information about the modulation of the plasma or information about a desired waveform of a piece of equipment connected to the plasma processing system.

A plasma processing apparatus that performs plasma processing on a substrate held on a transport carrier including an annular frame and a holding sheet. The apparatus includes a process chamber; a process gas supply unit that supplies process gas to the process chamber; a decompressing mechanism that decompresses the process chamber; a plasma excitation device that generates plasma in the process chamber; a stage in the chamber, on which the transport carrier is loaded; a cooling mechanism for cooling the stage; a cover that partly covers the holding sheet and the frame and that has a window section through which the substrate is partly exposed to plasma; a correction member that presses the frame onto the stage and corrects warpage of the frame; and a movement device that moves the correction member. The correction member is provided separately from the cover to be covered by the cover.

Described herein are architectures, platforms and methods for acquiring optical emission spectra from an optical emission spectroscopy system by flowing a dry cleaning gas into a plasma processing chamber of the plasma processing system and igniting a plasma in the plasma processing chamber to initiate the waferless dry cleaning process.

Disclosed is a substrate treating apparatus. The substrate treating apparatus includes a chamber having a treatment space in the interior thereof, a support unit configured to support a substrate in the treatment space, a gas supply unit configured to supply a gas into the treatment space, and a plasma generating unit configured to generate plasma from the gas, wherein the support unit includes an electrostatic chuck including an upper body having a support surface that suctions the substrate and a lower body extending from the upper body to a lower side, wherein the lower body has an extension part extending laterally from the upper body, a focus ring disposed on the extension part of the electrostatic chuck, and a metallic ring provided between the upper body of the electrostatic chuck and the focus ring and configured to control plasma in an extreme edge of the substrate.

A method for manufacturing an arrestor for an electrostatic chuck includes printing first layers of an arrestor for an electrostatic chuck using a 3-D printer and an electrically non-conductive material. The first layers of the arrestor at least partially define a first opening to a gas flow channel. The method includes printing intermediate layers of the arrestor using the 3-D printer and the electrically non-conductive material. The intermediate layers of the arrestor at least partially define the gas flow channel. The method includes printing second layers of the arrestor using the 3-D printer and the electrically non-conductive material. The second layers of the arrestor at least partially define a second opening of the gas flow channel. At least one of the first opening, the second opening and/or the gas flow channel of the arrestor is arranged to prevent a direct line of sight between the first opening and the second opening of the arrestor.

A substrate support assembly includes a shaft assembly, a pedestal coupled to a portion of the shaft assembly, and a first rotary connector coupled to the shaft assembly, wherein the first rotary connector comprises a first coil member surrounding a rotatable shaft member that is electrically coupled to the shaft assembly, the first coil member being rotatable with the rotatable shaft, and a second coil member surrounding the first coil member, the second coil member being stationary relative to the first coil member, wherein the first coil member electrically couples with the second coil member when the rotating radio frequency applicator is energized and provides a radio frequency signal/power to the pedestal through the shaft assembly.