A plasma lining structure is used in a process chamber to block direct line-of-sight for plasma generated within to grounded surface. The plasma lining structure includes a plurality of sections to cover at least one or more portions of an inside surface of a plasma confinement structure disposed in the process chamber. The sections of the plasma lining structure are positioned between a plasma region and the sidewall of the plasma confinement structure, when the plasma lining structure and the plasma confinement structure are disposed in the plasma chamber, such that the sections directly face the plasma region.

A structure comprising a substrate and a component which forms involatile metal etch products is plasma etched. A structure comprising a substrate and a component which forms involatile metal etch products is provided. The structure is positioned on a support within a chamber having a first gas inlet arrangement comprising one or more gas inlets and a second gas inlet arrangement comprising one or more gas inlets. The structure is etched by performing a first plasma etch step using a first etch process gas mixture which is only introduced into the chamber through the first gas inlet arrangement. The structure is further etched by performing a second plasma etch step using a second etch process gas mixture which is only introduced into the chamber through the second gas inlet arrangement.

A plasma generation apparatus includes a housing fitted in a portion of an upper surface of a process chamber of a deposition apparatus and having a protruding portion having an elongated shape in a plan view and protruding upward from a bottom surface, a coil wound around a side surface of the protruding portion and having an elongated shape in the plan view, and an inclination adjustment mechanism configured to independently move upward and downward both ends in a longitudinal direction of the coil to change an inclination of the coil in the longitudinal direction.

Processes for surface treatment of a workpiece are provided. In one example implementation, a method can include conducting a pre-treatment process on a processing chamber to generate a hydrogen radical affecting layer on a surface of the processing chamber prior to performing a hydrogen radical based surface treatment process on a workpiece in the processing chamber. In this manner, a pretreatment process can be conducted to condition a processing chamber to increase uniformity of hydrogen radical exposure to a workpiece.

A plasma source comprises a metal member having an inlet and forming a wall that delimits an upstream flow of a processing gas supplied from the inlet, a ceramic member having an outlet and forming a wall that delimits a downstream flow of the processing gas discharged from the outlet, and a power supply device configured to supply a power for plasma generation into a chamber. The chamber includes the metal member and the ceramic member, and is configured to discharge an activated gas generated by producing plasma from the processing gas to the outside of the chamber through the outlet.

Disclosed is a plasma film-forming method including: accommodating a workpiece in a chamber; supplying a film-forming gas into the chamber; generating plasma within the chamber; and exciting the film-forming gas by the plasma to form a predetermined film on the workpiece. Helium gas is supplied as a plasma generating gas into the chamber together with the film-forming gas to generate plasma containing the helium gas in the chamber.

An exemplary embodiment of the present invention provides a substrate treating apparatus, including: a chamber having an inner space; a shower head for partitioning the inner space into an upper first zone and a lower second zone, and formed with a plurality of through holes; a support unit for supporting a substrate in the second zone; a gas supply unit for supplying gas to the first zone; a plasma source for forming a plasma in the first zone by exciting the gas; and an adsorption plate coupled to the shower head, in which a surface of the adsorption plate is provided with a material that adsorbs radicals contained in the plasma.

Described herein is a method of depositing a plasma resistant ceramic coating onto a surface of a chamber component using a non-line-of-sight (NLOS) deposition process, such as atomic layer deposition (ALD) and chemical vapor deposition (CVD). The plasma resistant ceramic coating consists of an erbium containing oxide, an erbium containing oxy-fluoride, or an erbium containing fluoride. Also described are chamber components having a plasma resistant ceramic coating of an erbium containing oxide, an erbium containing oxy-fluoride, or an erbium containing fluoride.

Processing chamber components and methods of manufacture of same are provided herein. In some embodiments, a component part body includes a component part body having a base plane and at least one textured surface region, wherein the at least one textured surface region comprises a plurality of independent surface features having a first side having at least a 45 degree angle with respect to the base plane. In at least some embodiments, the textured surface includes a plurality of independent surface features which are pore free.

Embodiments described herein generally relate to a substrate support assembly having a shield cover. In one embodiment, a substrate support assembly is disclosed herein. The substrate support assembly includes a support plate, a plurality of RF return straps, at least one shield cover, and a stem. The support plate is configured to support a substrate. The plurality of RF return straps are coupled to a bottom surface of the support plate. At least one shield cover is coupled to the bottom surface of the support plate, between the plurality of RF return straps and the bottom surface. The stem is coupled to the support plate.