A plasma processing apparatus includes a stage in a processing chamber where plasma is formed, a wafer to be processed, and an electrode arranged at an upper part of the stage and supplied with power to electrostatically attract and hold the wafer on the stage, and consecutively processing a plurality of wafers one by one. There are plural processing steps of conducting processing using the plasma under different conditions and there are plural periods when formation of plasma is stopped between the processing steps. An inner wall of the processing chamber is coated before starting the processing of any wafer, and voltage supplied to the electrode is changed according to a balance of respective polarities of particles floating and charged in the processing chamber in each period when formation of plasma is stopped.

An apparatus for use in a plasma processing chamber is provided. The apparatus comprises part body and a coating with a thickness of no more than 30 microns consisting essentially of a Lanthanide series or Group III or Group IV element in an oxyfluoride covering a surface of the part body.

The present invention relates to a technology for increasing the reliability of measurement by preventing the contamination of a self-plasma chamber provided in order to monitor a deposition operation performed in a process chamber, and has a shielding means capable of preventing an inflow of negative electrode material, which is generated by a sputtering phenomenon, into a discharge chamber when a positive charge of plasma, which is generated in the self-plasma chamber, collides with a negative electrode.

A system to provide a texture to a surface of a component for use in a semiconductor processing chamber is provided. The system includes an enclosure comprising a processing region, a support disposed in the processing region, a photon light source to generate a stream of photons, an optical module operably coupled to the photon light source, and a lens. The optical module includes a beam modulator to create a beam of photons from the stream of photons generated from the photon light source, and a beam scanner to scan the beam of photons across the surface of the component. The lens is used to receive the beam of photons from the beam scanner and distribute the beam of photons at a wavelength in a range between about 345 nm and about 1100 nm across the surface of the component to form a plurality of features on the component.

Thermally conductive coatings are deposited on an inner surface of a particle containment chamber to mitigate excessive heating of the inner surface. A particle manipulation system includes a particle containment plasma containment chamber with a thermally-conductive coating comprising bort, graphite, and/or diamond on the inner surface of the chamber. The coating material and thickness can be selected to absorb a majority of energetic radiation (such as X-rays) incident on the coating and transport heat generated by the absorbed X-rays away from the inner surface of the chamber. Methods of deposition, including in situ deposition, are also described.

Described herein is a technique capable of suppressing sputtering on an inner peripheral surface of a process vessel when a process gas is plasma-excited in the process vessel. According to one aspect thereof, a substrate processing apparatus includes: a process vessel accommodating a process chamber where a process gas is excited into plasma; a gas supplier supplying the process gas into the process chamber; a coil wound around an outer peripheral surface of the process vessel and spaced apart therefrom, wherein a high frequency power is supplied to the coil; and an electrostatic shield disposed between the outer peripheral surface and the coil, wherein the electrostatic shield includes: a partition extending in a circumferential direction to partition between a part of the coil and the outer peripheral surface; and an opening extending in the circumferential direction and opened between another part of the coil and the outer peripheral surface.

Described herein is a technique capable of suppressing sputtering on an inner peripheral surface of a process vessel when a process gas is plasma-excited in the process vessel. According to one aspect thereof, a substrate processing apparatus includes: a process vessel accommodating a process chamber where a process gas is excited into plasma; a gas supplier supplying the process gas into the process chamber; a coil wound around an outer peripheral surface of the process vessel and spaced apart therefrom, wherein a high frequency power is supplied to the coil; and an electrostatic shield disposed between the outer peripheral surface and the coil, wherein the electrostatic shield includes: a partition extending in a circumferential direction to partition between a part of the coil and the outer peripheral surface; and an opening extending in the circumferential direction and opened between another part of the coil and the outer peripheral surface.

A ring assembly for a substrate support is disclosed herein. The ring assembly has a ring shaped body. The ring shaped body has an inner diameter and an outer diameter, a top surface, an inner portion at the inner diameter, and an outer portion at the outer diameter. A carbon based coating is disposed on the top surface of the ring shaped body, wherein the carbon based coating is thicker on the inner portion of the ring shaped body than the outer portion of the ring shaped body.