The present disclosure generally relates to an epitaxial chamber for processing of semiconductor substrates. In one example, the epitaxial chamber has a chamber body assembly. The chamber body assembly includes a lower window and an upper window, wherein chamber body assembly, the lower window and the upper window enclose an internal volume. A susceptor assembly is disposed in the internal volume. The epitaxial chamber also has a plurality of temperature control elements. The plurality of temperature control elements include one or more of an upper lamp module, a lower lamp module, an upper heater, a lower heater, or a heated gas passage.

A gas trap system for metal organic chemical vapor deposition (MOCVD) exhaust abatement operations is provided. The gas trap system may include a housing including an inlet configured to receive exhaust gas and an outlet. The gas trap system may also include a conical inlet shield positioned within the housing. The conical inlet shield may form a first path between the housing and the conical inlet shield, wherein the first path receives the exhaust gas from the inlet. The conical inlet shield may also cool the exhaust gas and cause the exhaust gas to be uniformly distributed in the first path. The gas trap system may also include a filter configured to receive the exhaust gas from the first path and to filter the exhaust gas, wherein the filtered gas exhaust is provided to the outlet.

Gas distribution assemblies and methods for providing a flow of gases to a process station are described. The gas distribution assemblies comprise a pumping liner with a showerhead and a gas funnel positioned therein. The pumping liner has an inner wall that slants at a first angle relative to a central axis of the gas distribution assembly so that the inner wall adjacent the bottom wall of the pumping liner is closer to the central axis than the inner wall adjacent the top wall. The gas funnel and pumping liner form a plenum between the outer wall of the gas funnel, a cavity in the bottom wall of the gas funnel and the inner wall of the pumping liner.

A technique capable of exhausting a process gas in a wide pressure range includes a substrate processing apparatus including: a process chamber; a gas supply system configured to supply a process gas containing a compound capable of reacting with a metal; and a gas exhaust system configured to exhaust an inner atmosphere of the process chamber, wherein the gas exhaust system includes: a common exhaust piping; a first exhaust piping made of a resin incapable of reacting with the compound and whose one end is connected to the common exhaust piping via a first valve and the other end is connected to a first exhauster; and a second exhaust piping made of the metal and whose one end is connected to the common exhaust piping via a second valve and the other end is connected to a second exhauster.

Aspects of the present disclosure relate generally to isolator devices, components thereof, and methods associated therewith for substrate processing chambers. In one implementation, a substrate processing chamber includes an isolator ring disposed between a pedestal and a pumping liner. The isolator ring includes a first surface that faces the pedestal, the first surface being disposed at a gap from an outer circumferential surface of the pedestal. The isolator ring also includes a second surface that faces the pumping liner and a protrusion that protrudes from the first surface of the isolator ring and towards the outer circumferential surface of the pedestal. The protrusion defines a necked portion of the gap between the pedestal and the isolator ring.

Methods and systems for dry cleaning a semiconductor processing reaction chamber are disclosed herein. In some embodiments, a method for cleaning a semiconductor processing reaction chamber includes: performing a plasma-assisted cleaning process to clean tube deposits formed on an inner surface of the deposition reaction chamber, the plasma-assisted cleaning process comprises: providing a first reactant gas to a remote plasma source chamber to generate a plasma, wherein the plasma comprising a fluorine-containing radical; and providing the plasma from the remote plasma source chamber to the deposition reaction chamber to clean the tube deposits, and performing a chemical cleaning process by providing a second reactant gas to the deposition reaction chamber after performing the plasma dry cleaning process.

Pumping liners for use in an apparatus for depositing a material on a work piece by chemical vapor deposition includes a plurality of unevenly spaced apertures are disclosed. Uneven spacing of the plurality of apertures produces a uniform flow of processing gases within a processing chamber with which the pumping liner is associated. Films of materials deposited onto a work piece by chemical vapor deposition techniques using disclosed pumping liners exhibit desirable properties such as uniform thickness and smooth and uniform surfaces.

Methods and devices are provided wherein rotational gas-flow is generated by vortex generators to decontaminate dirty gas (e.g., gas contaminated by solid particles) in pumping lines of vacuum systems suitable for use at a semiconductor integrated circuit fabrication facility. The vacuum systems use filterless particle decontamination units wherein rotational gas-flow is applied to separate and trap solid particles from gas prior to the gas-flow entering a vacuum pump. Methods are also described whereby solid deposits along portions of pumping lines may be dislodged and removed and portions of pumping lines may be self-cleaning.

In an embodiment, a method of forming a semiconductor device includes forming a hydrophobic coating on an inner surface of an exhaust line, connecting the exhaust line to a semiconductor processing chamber, introducing a first precursor into the semiconductor processing chamber, introducing a second precursor into the semiconductor processing chamber, wherein the first precursor reacts with the second precursor to form a layer of oxide material, and pumping the first precursor and the second precursor from the semiconductor processing chamber and through the exhaust line.

A thin film deposition system deposits a thin film on a substrate in a thin film deposition chamber. The thin film deposition system deposits the thin film by flowing a fluid into the thin film deposition chamber. The thin film deposition system includes a byproducts sensor that senses byproducts of the fluid in an exhaust fluid. The thin film deposition system adjusts the flow rate of the fluid based on the byproducts.