A vortical atomizing nozzle assembly, vaporizer, and related methods are disclosed for substrate processing systems. The vaporizer introduces an atomized or vaporized liquid into a substrate processing system and includes a vaporizer chamber, a nozzle assembly coupled to the inlet for the vaporizer chamber, and a carrier gas channel coupled to the nozzle assembly. The nozzle assembly includes a premix chamber, an outlet channel, and an expanding nozzle. The premix chamber includes a liquid inlet to receive the liquid to be vaporized and a gas inlet to receive the carrier gas. The carrier gas channel is positioned with respect to the gas inlet to cause a vortical flow within the premix chamber upon introduction of the carrier gas through the carrier gas channel. The premixed liquid from the premix chamber is received by the outlet channel and exits the outlet channel into the expanding nozzle.

A gas distribution system is disclosed in order to obtain better film uniformity on a substrate in a cross-flow reactor. The better film uniformity may be achieved by an asymmetric bias on individual injection ports of the gas distribution system. The gas distribution may allow for varied tunability of the film properties.

Embodiments disclosed herein generally relate to a gas distribution assembly for providing improved uniform distribution of processing gases into a semiconductor processing chamber. The gas distribution assembly includes a gas distribution plate, a blocker plate, and a dual zone showerhead. The gas distribution assembly provides for independent center to edge flow zonality, independent two precursor delivery, two precursor mixing via a mixing manifold, and recursive mass flow distribution in the gas distribution plate.

Disclosed are methods and systems for filling a gap. A method comprises providing a substrate to a reaction chamber. The substrate comprises the gap. The method further comprises at least partially filling the gap with a gap filling fluid. The method then comprises subjecting the gap filling fluid to a transformation treatment, thus forming a transformed material in the gap. The methods and systems are useful, for example, in the field of integrated circuit manufacture.

A plasma source has an outer surface, interrupted by an aperture for delivering an atmospheric plasma from the outer surface. A transport mechanism transports a substrate in parallel with the outer surface, closely to the outer surface, so that gas from the atmospheric plasma may form a gas bearing between the outer surface the and the substrate. A first electrode of the plasma source has a first and second surface extending from an edge of the first electrode that runs along the aperture. The first surface defines the outer surface on a first side of the aperture. The distance between the first and second surface increasing with distance from the edge. A second electrode covered at least partly by a dielectric layer is provided with the dielectric layer facing the second surface of the first electrode, substantially in parallel with the second surface of the first electrode, leaving a plasma initiation space on said first side of the aperture, between the surface of the dielectric layer and the second surface of the first electrode. A gas inlet feeds into the plasma initiation space to provide gas flow from the gas inlet to the aperture through the plasma initiation space. Atmospheric plasma initiated in the plasma initiation space flows to the aperture, from which it leaves to react with the surface of the substrate.

A method and apparatus that may be utilized for chemical vapor deposition and/or hydride vapor phase epitaxial (HVPE) deposition are provided. In one embodiment, a metal organic chemical vapor deposition (MOCVD) process is used to deposit a Group III-nitride film on a plurality of substrates. A Group III precursor, such as trimethyl gallium, trimethyl aluminum or trimethyl indium and a nitrogen-containing precursor, such as ammonia, are delivered to a plurality of straight channels which isolate the precursor gases. The precursor gases are injected into mixing channels where the gases are mixed before entering a processing volume containing the substrates. Heat exchanging channels are provided for temperature control of the mixing channels to prevent undesirable condensation and reaction of the precursors.

An LPCVD apparatus is provided with a processing chamber and a reaction cooling apparatus. The reaction cooling apparatus is placed outside the processing chamber and is configured to generate hydrogen fluoride gas by reaction of hydrogen gas and fluorine gas and to cool the hydrogen fluoride gas. The hydrogen fluoride gas cooled by the reaction cooling apparatus is supplied into the processing chamber as a cleaning gas.

The invention relates to an apparatus for depositing thin film coatings on a substrate. The deposition apparatus is designed to keep gaseous reactant materials to be deposited apart from one another in the deposition apparatus, by one or more separation devices and/or methods, but nevertheless, to allow the chemical reactants to mix and react at or near the substrate surface, rapidly enough to create a uniform film at commercially viable deposition rates.

The present application provides a gas showerhead including a gas distribution and diffusion plate and a water cooling plate, the gas distribution and diffusion plate includes several columns of first gas diffusion passages connecting to a first reactant gas source and several columns of second gas diffusion passages connecting to a second reactant gas source; the water cooling plate having cooling liquid passages is arranged below the gas distribution and diffusion plate, and the water cooling plate is provided with first gas outlet passages provided for the reactant gas in the first gas diffusion passages to flow out and second gas outlet passages provided for the reactant gas in the second gas diffusion passages to flow out, so as to isolatedly feed at least two reactant gases into a reaction chamber.

Provided are a metal chalcogenide thin film and a method and device for manufacturing the same. The metal chalcogenide thin film includes a transition metal element and a chalcogen element, and at least one of the transition metal element and the chalcogen element having a composition gradient along the surface of the metal chalcogenide thin film, the composition gradient being an in-plane composition gradient. The metal chalcogenide thin film may be prepared by using a manufacturing method including providing a transition metal precursor and a chalcogen precursor on a substrate by using a confined reaction space in such a manner that at least one of the transition metal precursor and the chalcogen precursor forms a concentration gradient according to a position on the surface of the substrate; and heat-treating the substrate.