A method of processing a substrate is provided. The method processes a substrate by using a substrate processing apparatus including a chamber, a shower head unit for supplying a cleaning gas into the chamber, a first electrode disposed on an upper portion of the shower head unit, a support unit for supporting the substrate, and a second electrode disposed inside the support unit, the method including supplying the cleaning gas into the chamber, and supplying a voltage of a first magnitude to the first electrode and supplying a voltage of a second magnitude greater than the first magnitude to the second electrode.

A wafer support table includes a ceramic base and a rod. The ceramic base has a wafer placement surface and includes an RF electrode and a heater electrode that are embedded therein in the mentioned order from the side closer to the wafer placement surface. A hole is formed in the ceramic base to extend from a rear surface toward the RF electrode. The rod is made of Ni or Kovar, is bonded to a tablet exposed at a bottom surface of the hole, and supplies radio-frequency electric power to the RF electrode therethrough. An Au thin film is coated over a region of an outer peripheral surface of the rod ranging from a base end of the rod to a predetermined position.

An edge ring system comprising a substrate support configured to support a substrate during plasma processing and including a baseplate and an upper layer arranged on the baseplate. An edge ring support includes a first body and an electrostatic clamping electrode arranged in the first body. The edge ring support is arranged above the baseplate and radially outside of the substrate during processing. An edge ring includes a second body arranged on and electrostatically clamped to the edge ring support during plasma processing.

Disclosed is a plasma processing system with a faraday shielding device. The plasma processing system comprises a reaction chamber, and a faraday shielding device and an air inlet nozzle which are located on the reaction chamber. The air inlet nozzle penetrates through the faraday shielding device to introduce process gas into the reaction chamber. The air inlet nozzle is made of a conductive material, and the air inlet nozzle is electrically connected to the faraday shielding device. According to the plasma processing system, the air inlet nozzle made of the conductive material is electrically connected to the faraday shielding device, when the cleaning process is carried out, reaction gas of the cleaning process in the projection area of the air inlet nozzle is also electrically isolated, the reaction gas of the cleaning process forms a capacitive coupling plasma in the whole region below a dielectric window.

An upper electrode assembly used in a plasma processing apparatus is provided. The upper electrode assembly comprises: an electrode plate; a metal plate; and a heat transfer sheet disposed between the electrode plate and the metal plate and having a vertically oriented portion. The vertically oriented portion has a plurality of vertically oriented graphene structures oriented along a vertical direction.

A deposition apparatus and a method are provided. A method includes placing a substrate over a platform in a chamber of a deposition system. A precursor material is introduced into the chamber. A first gas curtain is generated in front of a first electromagnetic (EM) radiation source coupled to the chamber. A plasma is generated from the precursor material in the chamber, wherein the plasma comprises dissociated components of the precursor material. The plasma is subjected to a first EM radiation from the first EM radiation source. The first EM radiation further dissociates the precursor material. A layer is deposited over the substrate. The layer includes a reaction product of the dissociated components of the precursor material.

Disclosed are plasma edge rings, plasma etching apparatuses, and plasma etching methods. The plasma etching apparatus comprises a plasma electrode, a plasma edge ring on the plasma electrode, and a guide electrode outside an etching target on the plasma electrode. The plasma edge ring provides a placement hole that vertically penetrates a center of the plasma edge ring, and a recess on a portion of an inner lateral surface that defines the placement hole. The recess is outwardly recessed from the inner lateral surface.

Provided are a substrate processing apparatus and a method of manufacturing a semiconductor device using the same. The substrate processing apparatus includes a lower electrode assembly, an upper electrode assembly disposed on the lower electrode assembly, and a plasma processing region between the lower electrode assembly and the upper electrode assembly. The lower electrode assembly includes a substrate support supporting a substrate, a coupling ring assembly surrounding the substrate support, an edge ring on the coupling ring assembly, and at least one upper contact pad contacting a lower surface of the edge ring and contacting at least one of the substrate support and the coupling ring assembly, the at least one upper contact pad being conductive. The coupling ring assembly includes a coupling ring and a conductive side contact pad in contact with a side surface of the substrate support and an inner surface of the coupling ring.

Aspects of the present disclosure relate generally to pedestals, components thereof, and methods of using the same for substrate processing chambers. In one implementation, a pedestal for disposition in a substrate processing chamber includes a body. The body includes a support surface. The body also includes a stepped surface that protrudes upwards from the support surface. The stepped surface is disposed about the support surface to surround the support surface. The stepped surface defines an edge ring such that the edge ring is integrated with the pedestal to form the body that is monolithic. The pedestal also includes an electrode disposed in the body, and one or more heaters disposed in the body.

There is provided a technique that includes: a process chamber in which a substrate is processed; a plurality of first electrodes; a plurality of second electrodes; a high-frequency power supply configured to supply a high-frequency power; a high-frequency power application plate configured to connect the plurality of first electrodes to the high-frequency power supply; and a grounding plate configured to ground the plurality of second electrodes.