A plasma processing apparatus includes a baffle structure between a mounting table and a processing chamber. The baffle structure has a first member and a second member. The first member has a first cylindrical part extending between the mounting table and the processing chamber, and a plurality of through-holes elongated in the vertical direction is formed in an array in the circumferential direction in the first cylindrical part. The second member has a second cylindrical part having an inner diameter greater than the outer diameter of the cylindrical part for the first member. The second member moves up and down in a region that includes the space between the first member and the processing chamber.

Chamber components for an epitaxial growth apparatus are disclosed. A reaction chamber defined and formed by a ceiling plate. A reactant gas is rectified in a reactant gas supply path disposed in the side wall, so that a horizontal component in a flow direction of the reactant gas in the reaction chamber corresponds to a horizontal component in a direction extending from the center of an opening of the reactant gas supply path. Improvements to the upper side wall, susceptor and rectification plate of the epitaxial growth apparatus have resulted in improvements to the uniformity and formation speed of the epitaxial layer formed on substrates resulting in higher throughput and lower defects.

A stage for mounting a workpiece and an edge ring is provided, the stage including a first flow path and a second flow path along each of which a fluid flows, within the stage; a bifurcation at which an inlet port of the first flow path and an inlet port of the second flow path are coupled; a junction at which an outlet port of the first flow path and an outlet port of the second flow path are coupled; and a member provided at least one of the bifurcation and the junction, the member having at least one opening that communicates with the first flow path and the second flow path.

A film-forming device that includes a cylindrical chamber capable of maintaining vacuum therein, a workpiece holder that is constructed to align and hold workpieces to be processed in multiple stages such that main surfaces of the workpieces are oriented in a vertical direction relative to a central axis of the chamber, a deposition material supply pipe, a modifier supply pipe, a carrier gas supply pipe, and an exhaust mechanism, wherein in a cross section of the chamber in a direction parallel to the main surfaces of the workpieces, the exhaust mechanism is located on a side opposite to an opening direction of gas outlets of the deposition, modifier, and carrier gas supply pipes, and a total gas flow from the deposition, modifier, and carrier gas supply pipes is symmetric about a centerline of the chamber.

A processing apparatus includes: a processing container having a substantially cylindrical shape and provided with an exhaust slit on a side wall; and a plurality of gas nozzles extending in a vertical direction along an inside of the side wall of the processing container, disposed symmetrically with respect to a straight line connecting a center of the processing container and a center of the exhaust slit, and each configured to eject a same processing gas into the processing container.

A gas injection apparatus for a thermal processing chamber includes a gas injector having an inlet at a first end and a port at a second end; and a plate having a first opening matching the port, one or more second openings, and at least one circuitous flow path defined by the plate and fluidly connecting the first opening to the one or more second openings.

A gas injection system, a reactor system including the gas injection system, and methods of using the gas injection system and reactor system are disclosed. The gas injection system can be used in gas-phase reactor systems to independently monitor and control gas flow rates in a plurality of channels of a gas injection system coupled to a reaction chamber.

Embodiments described herein provide an apparatus for improving deposition uniformity by improving plasma profile using a tri-cut chamber liner. The apparatus also includes a lid assembly having a split process stack for reducing downtime and a bottom heater support for more efficient heating of chamber walls.

A plasma processing apparatus includes a baffle structure between a mounting table and a processing chamber. The baffle structure has a first member and a second member. The first member has a first cylindrical part extending between the mounting table and the processing chamber, and a plurality of through-holes elongated in the vertical direction is formed in an array in the circumferential direction in the first cylindrical part. The second member has a second cylindrical part having an inner diameter greater than the outer diameter of the cylindrical part for the first member. The second member moves up and down in a region that includes the space between the first member and the processing chamber.

Embodiments disclosed herein generally relate to a chamber liner for the high temperature processing of substrates in a processing chamber. The processing chamber utilizes an inert bottom purge flow to shield the substrate support from halogen reactants such that the substrate support may be heated to temperatures greater than about 650 degrees Celsius. The chamber liner controls a flow profile such that during deposition the bottom purge flow restricts reactants and by-products from depositing below the substrate support. During a clean process, the bottom purge flow restricts halogen reactants from contacting the substrate support. As such, the chamber liner includes a conical inner surface angled inwardly to direct purge gases around an edge of the substrate support and to reduce deposition under the substrate support and the on the edge.