Exemplary semiconductor processing chamber showerheads may include a dielectric plate characterized by a first surface and a second surface opposite the first surface. The dielectric plate may define a plurality of apertures through the dielectric plate. The dielectric plate may define a first annular channel in the first surface of the dielectric plate, and the first annular channel may extend about the plurality of apertures. The dielectric plate may define a second annular channel in the first surface of the dielectric plate. The second annular channel may be formed radially outward from the first annular channel. The showerheads may also include a conductive material embedded within the dielectric plate and extending about the plurality of apertures without being exposed by the apertures. The conductive material may be exposed at the second annular channel.

There is provided a technique that includes: a cylindrical outer tube; an inner tube that is installed inside the outer tube and configured such that a substrate is capable of being processed in a process chamber formed in the inner tube; a manifold that is installed below the outer tube and the inner tube, in fluid communication with an internal space of the inner tube, and formed in a cylindrical shape with an exhaust space isolated from an annular space between the inner tube and the outer tube; a process gas nozzle configured to supply a process gas that processes the substrate to an inside of the inner tube; a purge gas nozzle configured to supply a purge gas to the annular space; and a conductance changer that is installed at a partition wall between the annular space and the exhaust space.

A vapor deposition apparatus for providing a deposition film on a substrate, the vapor deposition apparatus includes a plurality of first nozzle parts which injects a first raw material toward the substrate; a plurality of second nozzle parts which is alternately disposed together with the plurality of first nozzle parts and injects a second raw material toward the substrate; a diffuser unit which distributes the second raw material to the plurality of second nozzle parts; and a supply unit which supplies the second raw material to the diffuser unit.

Embodiments disclosed herein generally include an apparatus for radical-based deposition of dielectric films. The apparatus includes a processing chamber, a radical source coupled to the processing chamber, a substrate support disposed in the processing chamber, and a dual-channel showerhead disposed between the radical source and the substrate support. The dual-channel showerhead includes a plurality of tubes and an internal volume surrounding the plurality of tubes. The plurality of tubes and the internal volume are surrounded by one or more annular channels embedded in the dual-channel showerhead. The dual-channel showerhead further includes a first inlet connected to the one or more channels and a second inlet connected to the internal volume. The processing chamber may be a PECVD chamber, and the apparatus is capable of performing a cyclic process (alternating radical based CVD and PECVD).

The invention concerns a reactor for chemical vapour deposition from first and second precursor gases, the reactor comprising: —a chamber including top and bottom walls and a side wall linking the top and bottom walls, —a support intended for receiving at least one substrate, mounted inside the chamber, and —at least one system for injecting precursor gases, the system comprising an injection head including at least one nozzle for supplying the first precursor gas (41) in a main direction of axis A-A′, the at least one nozzle including: a precursor gas supply conduit (321), and an outlet member (322) generating a substantially annular 43 vortex flow (44) around axis A-A′.

A method for manufacturing a SiC epitaxial wafer according to one aspect of the present invention includes separately introducing, into a reaction space for SiC epitaxial growth, a basic N-based gas composed of molecules containing an N atom within the molecular structure but having neither a double bond nor a triple bond between nitrogen atoms, and a Cl-based gas composed of molecules containing a Cl atom within the molecular structure, and mixing the N-based gas and the Cl-based gas at a temperature equal to or higher than the boiling point or sublimation temperature of a solid product generated by mixing the N-based gas and the Cl-based gas.

A method that includes performing an atomic layer deposition sequence including at least one deposition cycle, each cycle producing a monolayer of deposited material, the deposition cycle including introducing at least a first precursor species and a second precursor species to a substrate surface in a reaction chamber, wherein both of said first and second precursor species are present in gas phase in said reaction chamber simultaneously.

Plasma processing conditions may be changed for localized regions of a substrate. A reactive gas may be maintained in a localized region of a substrate while other regions of the substrate are not exposed to the reactive gas. Thus, plasma conditions may be generated at specific regions of the substrate. A multi-zoned gas injection system may be utilized to direct certain gases in certain regions of the plasma space. Techniques may be provided to maintain these gases in the desired regions, as opposed to the gases spreading across the substrate surface. Reactive gases may be provided in one region while a flow of inert gas is provided in other regions in which it is desired to restrict the effects of the reactive gases. Localized control of the plasma process may be provided as a separate plasma processing step. The localized region of the substrate may be the substrate edge.

Disclosed are a liner assembly for vacuum treatment apparatuses and a vacuum treatment apparatus, wherein the liner assembly for vacuum treatment apparatuses comprises: an annular liner including a sidewall protection ring and a support ring which are interconnected, the outer diameter of the support ring being greater than that of the sidewall protection ring, the annular liner enclosing a treating space; and a gas channel provided in the support ring, the gas channel communicating with the treating space. The liner assembly for vacuum treatment apparatuses offer an improved performance.

Aspects of the present disclosure provide systems and apparatuses for a substrate processing assembly with a laminar flow cavity gas injection for high and low pressure. A dual gas reservoir assembly is provided in a substrate processing chamber, positioned within a lower shield assembly. A first gas reservoir is in fluid communication with a processing volume of the substrate processing assembly via a plurality of gas inlet, positioned circumferentially about the processing volume. A second gas reservoir is positioned circumferentially about the first gas reservoir, coupled therewith via one or more reservoir ports. The second gas reservoir is in fluid communication with a first gas source. A recursive path gas assembly is positioned in an upper shield body adjacent to an electrode to provide one or more gases to a dark space gap.