Provided is an apparatus for processing a substrate using plasma, in which an etching rate can be controlled using an insulation plate provided with an air-gap. The substrate processing apparatus includes a chamber including a processing space for processing a substrate using plasma, and a support module located in the processing space and for supporting the substrate, wherein the support module includes a support plate for receiving high frequency power and a first surface disposed under the support plate and facing the support plate, and at least one first recess is formed on the first surface.

A liner assembly for a substrate processing system includes a first liner and a second liner. The first liner includes an annular body and an outer peripheral surface including a first fluid guide. The first fluid guide is curved about a circumferential line extending around the first liner. The second liner includes an annular body, an outer rim, an inner rim, a second fluid guide extending between the outer rim and the inner rim, and a plurality of partition walls extending outwardly from the second fluid guide. The second fluid guide is curved about the circumferential line when the first and second liners are positioned within the processing system.

A chemical vapor deposition system for coating one or more workpieces is described herein. The deposition system includes a plurality of processing chambers which may be operated independently to increase throughput of the deposition system. Each chamber includes a modular fixture that is configured to maintain the workpieces in a predetermined arrangement which allows for a hollow cathode effect to be maintained in an Interior space of the chamber. The deposition system achieves significantly faster, higher-quality deposition and more complete, conformal coverage.

Disclosed is a corrosion-resistant structure for a gas delivery system in a plasma processing apparatus. By providing a plating layer of corrosion-resistant material at the parts including the gas channel to avoid reacting with the delivered corrosive gas, metal and particle contaminations are reduced. By reversely mounting nozzles such that they reliably cover the plating layer inside the gas outlet holes, the disclosure prevents the corrosion-resistant material from being damaged by the plasma generated inside the cavity. By forming a corrosion-resistant yttrium oxide coating at the surfaces of the nozzles exposed to the cavity, the disclosure prevents the plasma from eroding the nozzles. The disclosure further leverages a flexible corrosion-resistant material, such as Teflon, to the sealing surfaces of the liner in contact with the dielectric window and the cavity, which improves the overall sealing effect of the liner. The disclosure may effectively enhance the corrosion-resistant and sealing properties of the liner and prolong its service life, as well as improving operating stability of the plasma processing apparatus.

Plasma processing apparatus and associated methods are provided. In one example, a plasma processing apparatus includes a plasma chamber. The plasma processing apparatus includes a dielectric wall forming at least a portion of the plasma chamber. The plasma processing apparatus includes an inductive coupling element located proximate the dielectric wall. The plasma processing apparatus includes an ultraviolet light source configured to emit an ultraviolet light beam onto a metal surface that faces an interior volume of the plasma chamber. The plasma processing apparatus includes a controller configured to control the ultraviolet light source.

Embodiments of process kits for use in a process chamber are provided herein. In some embodiments, a process kit for use in a process chamber includes a slit door having an arcuate profile and including a first plate slidably coupled to a second plate, wherein the first plate is configured to be coupled to an actuator, wherein the second plate has an inner surface that includes silicon, and wherein the inner surface includes a plurality of grooves.

An electrostatic puck assembly includes an upper puck plate, a lower puck plate and a backing plate. The upper puck plate comprises AlN or Al.sub.2O.sub.3 and has a first coefficient of thermal expansion. The lower puck plate comprises a material having a second coefficient of thermal expansion that approximately matches the first coefficient of thermal expansion and is bonded to the upper puck plate by a first metal bond. The backing plate comprises AlN or Al.sub.2O.sub.3 and is bonded to the lower puck plate by a second metal bond.

An etching method in accordance with the present disclosure includes providing a substrate, which includes a silicon-containing film, in a chamber; and etching the silicon-containing film with a chemical species in plasma generated from a process gas supplied in the chamber. The process gas includes a phosphorus gas component and a fluorine gas component.

A substrate processing system is disclosed. The system comprises a first chamber having a first substrate transfer port; a second chamber having a second substrate transfer port and configured to perform substrate processing; a connecting member that allows the first substrate transfer port and the second substrate transfer port to communicate with each other; a heat shield portion disposed along the second transfer port in cross-sectional view and configured to thermally block the first chamber and the second chamber from each other; and a protective member disposed between the heat shield portion and the second transfer port and configured to prevent deterioration of the heat shield portion during substrate processing in the second chamber.

A liner assembly for a substrate processing system includes a first liner and a second liner. The first liner includes an annular body and an outer peripheral surface including a first fluid guide. The first fluid guide is curved about a circumferential line extending around the first liner. The second liner includes an annular body, an outer rim, an inner rim, a second fluid guide extending between the outer rim and the inner rim, and a plurality of partition walls extending outwardly from the second fluid guide. The second fluid guide is curved about the circumferential line when the first and second liners are positioned within the processing system.