Exemplary semiconductor processing chambers may include a substrate support positioned within a processing region of the semiconductor processing chamber. The chamber may include a lid plate. The chamber may include a gasbox positioned between the lid plate and the substrate support. The gasbox may be characterized by a first surface and a second surface opposite the first surface. The gasbox may define a central aperture. The gasbox may define an annular channel in the first surface of the gasbox extending about the central aperture through the gasbox. The gasbox may include an annular cover extending across the annular channel defined in the first surface of the gasbox. The chamber may include a blocker plate positioned between the gasbox and the substrate support. The chamber may include a ferrite block positioned between the lid plate and the blocker plate.

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.

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.

Disclosed are methods and systems for filling a gap. An exemplary method comprises providing a substrate to a reaction chamber. The substrate comprises the gap. The method further comprises forming a gap filling process by means of a plasma-enhanced deposition process. The gap filling fluid at least partially fills the gap. The methods and systems are useful, for example, in the field of integrated circuit manufacture.

A film formation method according to one aspect of the present disclosure includes: a first step of irradiating a substrate, on which a recess is formed, with an electron beam; a second step of supplying a raw material gas to the substrate and allowing the raw material gas to be adsorbed on a bottom surface of the recess; and a third step of supplying hydrogen radicals to the substrate and allowing the raw material gas adsorbed on the bottom surface of the recess to react with the hydrogen radicals.

A film forming apparatus sequentially supplies a raw material gas of a compound containing chlorine and an element other than the chlorine, and a first reaction to form a fil. The film forming apparatus includes a rotary table, a raw material gas ejection port configured to eject the raw material gas to a first region, a reaction gas supply part configured to supply, to a second region, a first reaction gas and a second reaction gas that reacts with chlorine to generate a third reaction product, in order to prevent a second reaction product from being generated due to a reaction of the chlorine remaining in the vacuum container with air when performing the opening-to-air. The film forming apparatus further includes an atmosphere separation part, a first exhaust port and a second exhaust port, and a controller.

A film forming apparatus sequentially supplies a raw material gas of a compound containing chlorine and an element other than the chlorine, and a first reaction to form a fil. The film forming apparatus includes a rotary table, a raw material gas ejection port configured to eject the raw material gas to a first region, a reaction gas supply part configured to supply, to a second region, a first reaction gas and a second reaction gas that reacts with chlorine to generate a third reaction product, in order to prevent a second reaction product from being generated due to a reaction of the chlorine remaining in the vacuum container with air when performing the opening-to-air. The film forming apparatus further includes an atmosphere separation part, a first exhaust port and a second exhaust port, and a controller.

A substrate processing apparatus includes: a gas injection portion including two gas distribution portions, disposed on an upper portion in the chamber and spatially separated from each other, and two types of nozzles, respectively connected to the two gas distribution portions, having different lengths to each other; a first electrode, connected to a radio-frequency (RF) power supply and disposed below the gas injection portion to be vertically spaced apart from the gas injection portion, having a plurality of openings into which among the nozzles, one type of nozzles are respectively inserted; and a second electrode, disposed to oppose the first electrode, mounting a substrate.

A raw material supply apparatus includes: a container configured to store a solution obtained by dissolving a first solid raw material in a solvent or a dispersion system obtained by dispersing the first solid raw material in a dispersion medium; an injection part configured to spray the solution or the dispersion system to inject the solution or the dispersion system into the container; an exhaust port configured to exhaust an inside of the container; a heating part configured to heat a second solid raw material formed by removing the solvent or the dispersion medium from the solution or the dispersion system; and a deposition part provided between the injection part and the exhaust port in the container and configured to deposit the second solid raw material.

A raw material supply apparatus includes: a container configured to store a solution obtained by dissolving a first solid raw material in a solvent or a dispersion system obtained by dispersing the first solid raw material in a dispersion medium; an injection part configured to spray the solution or the dispersion system to inject the solution or the dispersion system into the container; an exhaust port configured to exhaust an inside of the container; a heating part configured to heat a second solid raw material formed by removing the solvent or the dispersion medium from the solution or the dispersion system; and a deposition part provided between the injection part and the exhaust port in the container and configured to deposit the second solid raw material.