Embodiments described herein generally relate to a processing system and a method of delivering a reactant gas. The processing system includes a substrate support system, an injection cone, and an intake. The injection cone includes a linear rudder. The linear rudder is disposed such that the flow of reactant gas through the injection cone results in film growth on a specific portion of a substrate. The method includes flowing the gas through the injection cone and delivering the gas onto the substrate below. The localization of the reactant gas, allows for film growth on a specific portion of the substrate.

The present invention relates to a susceptor including a substrate including a carbon material and having one main surface on which a silicon water is to be placed, and another main surface facing the one main surface, in which an entire surface of the substrate is covered with a thin film including silicon carbide, the one main surface has an emissivity variation of 3% or less, and a ratio of an average emissivity between the one main surface and the another main surface facing the one main surface is from 1:1 to 1:0.8.

A showerhead includes a shower plate and a base member including a gas flow path, the base member fixing the shower plate. The showerhead includes gas supply members disposed at a gas diffusion space, the gas diffusion space being provided between the shower plate and the base member, the gas supply members being connected to the gas flow path, each of the gas supply members including outlets via which gas is radially discharged, and the gas supply members being arranged such that the gas discharged via the outlets of the gas supply members generates a rotational flow.

A cleaning method that removes contaminants adhering to a stage in a chamber, includes: setting a pressure in a chamber to a predetermined vacuum pressure; supplying a first gas that forms a shock wave toward the stage; and supplying a second gas that does not form the shock wave toward the stage.

A substrate processing apparatus includes: a substrate retainer configured to support a substrate; a heat-insulating unit; a transfer chamber; and a gas supply mechanism configured to supply a gas into the transfer chamber, the gas supply mechanism including: a first gas supply mechanism configured to supply the gas into an upper region of the transfer chamber, where the substrate retainer is disposed such that the gas flows horizontally through the upper region; and a second gas supply mechanism configured to supply the gas into a lower region of the transfer chamber, where the heat-insulating unit is provided such that the gas flows downward through the lower region, wherein the first gas supply mechanism and the second gas supply mechanism are disposed along a first sidewall of the transfer chamber, and the second gas supply mechanism is disposed lower than the first gas supply mechanism.

A method includes forming a film on a substrate by performing a cycle a predetermined number of times, the cycle including non-simultaneously performing: (a) forming a first layer by supplying a precursor to the substrate; and (b) forming a second layer by supplying a reactant to the substrate and modifying the first layer. The (a) includes: (a-1) supplying the precursor to the substrate from a first supply part while supplying an inert gas at a first flow rate, and supplying an inert gas at a second flow rate from a second supply part; and (a-2) supplying the precursor to the substrate while supplying the inert gas at a third flow rate from the first supply part, or supplying the precursor from the first supply part while stopping the supply of the inert gas, and supplying the inert gas at a fourth flow rate from the second supply part.

A film forming method includes: rotating a rotary table to revolve a substrate which is placed on the rotary table and has a recess in its surface; supplying a raw material gas to a first region on the rotary table; supplying an ammonia gas to a second region on the rotary table; forming a first SiN film in the recess by supplying the raw material gas to the first region and supplying the ammonia gas to the second region at a first flow rate, while the rotary table rotates at a first rotation speed; and forming a second SiN film in the recess such that the second SiN film is laminated on the first SiN film by supplying the raw material gas to the first region and supplying the ammonia gas to the second region at a second flow rate, while the rotary table rotates at a second rotation speed.

A system and method for enhancing a diffusion limited CVI/CVD process is provided. The system may densify a porous structure by flowing a reactant gas around the porous structure. A mass flow controller may be configured to pulse the flow rate of the reactant gas around the porous structure. The mass flow controller may pulse the flow rate from a nominal flow rate to a first flow rate. The mass flow controller may pulse the first flow rate back to the nominal flow rate or to a second flow rate. The mass flow controller may pulse the flow rate between the nominal flow rate, the first flow rate, and the second flow rate, as desired.

Embodiments of the present disclosure generally relate to a processing chamber for conformal oxidation of high aspect ratio structures. The processing chamber includes a chamber body with a first side and a second side opposite the first side, and a flow assembly disposed in the first side. The flow assembly includes a flow divider to direct fluid flow away from a center of a substrate disposed in a processing region of the processing chamber. The flow divider includes a crescent shaped first side, a top, and a bottom. The processing chamber also includes a distributed pumping structure located adjacent to the second side. The flow assembly is designed to reduce flow constriction of the radicals, leading to increased radical concentration and flux.

The present disclosure provides an epitaxial device and a gas intake structure configured for the epitaxial device. The epitaxial device includes a chamber, a submount, a gas intake structure, and an exhaust structure. The gas intake structure includes: a plurality of first gas intake passages configured to provide a first process gas containing a gas for an epitaxial reaction to a to-be-processed surface along a first direction, the first direction being parallel to the to-be-processed surface; and two second gas intake passages that are arranged at intervals along a second direction, and correspond to two adjustment areas adjacent to edges on both sides of the to-be-processed surface respectively, where at least one first gas intake passage is disposed between the two second gas intake passages, each second gas intake passage provides a second process gas to the corresponding adjustment area along the first direction, and the second process gas is configured to adjust a concentration of the gas for the epitaxial reaction flowing through the adjustment areas. The epitaxial device and the gas intake structure provided by the embodiments of the present disclosure improve uniformity of thickness distribution of an epitaxial layer formed on the entire to-be-processed surface.