An exclusion ring for semiconductor wafer processing includes an outer circumferential segment having a first thickness and an inner circumferential segment having a second thickness, with the first thickness being greater than the second thickness. The top surface of an inner circumferential segment and the top surface of the outer circumferential segment define a common top surface for the exclusion ring. A plurality of flow paths is formed within the outer circumferential segment, with each of the flow paths extending radially through the plurality of flow paths provides for exhaust of a wafer edge gas from the pocket where a wafer has an edge thereof disposed below part of the inner circumferential portion. The exhausting of the wafer edge gas from the pocket prevents up-and-down movement of the exclusion ring when bowed wafers are processed.

An installation having a housing, a substrate support (20) received in the housing, diffuser (42) for diffusing an inert gas towards the substrate support, and at least one head (30) defining an inner volume (V) opened opposite to the top, the head being provided with at least two electrodes (8, 8′, 8″) for creating an electric discharge and with an injector (7, 7′, 7″) for injecting a gaseous mixture towards the substrate. The injector has at least one injection tube (7, 7′, 7″) placed between two adjacent electrodes or between one electrode and a peripheral wall, the tube being provided with injection holes facing the substrate support, for injecting the gaseous mixture on the substrate, whereas diffuser is provided inside the head, the injection tube being placed between the substrate support and the diffuser so that, in use, the gaseous mixture is urged against the substrate by the inert gas.

Provided are a deposition process monitoring system capable of detecting an internal state of a chamber in a deposition process, and a method of controlling the deposition process and a method of fabricating a semiconductor device using the system. The deposition process monitoring system includes a facility cover configured to define a space for a deposition process, a chamber located in the facility cover, covered with a translucent cover dome, and having a support on which a deposition target is placed, a plurality of lamps disposed in the facility cover, the lamps respectively disposed above and below the chamber, the lamps configured to supply radiant heat energy into the chamber during the deposition process, and a laser sensor disposed outside the chamber, the laser sensor configured to irradiate the cover dome with a laser beam and detect an intensity of the laser beam transmitted through the cover dome, wherein a state of by-products with which the cover dome is coated is determined based on the detected intensity of the laser beam.

Disclosed is a substrate processing apparatus that includes: a polishing table; an atomizer configured to spray a fluid to a polishing surface; a polishing liquid supply nozzle configured to drop a slurry at a position that corresponds to a slurry dropping position set on the polishing table and is lower than the top surface of the atomizer; a nozzle moving mechanism configured to move the polishing liquid supply nozzle above the atomizer between the retreat position set outside the polishing table and the slurry dropping position; and a nozzle tip retreating mechanism configured to bring the tip end of the polishing liquid supply nozzle into a retreated position above the top surface of the atomizer when the polishing liquid supply nozzle moves between the slurry dropping position and the retreat position.

The present invention decreases the impurity concentration of polycrystalline silicon to be produced. An apparatus (1) for producing polycrystalline silicon (S1) includes: a reactor (10) that contains a raw material gas (G1) for silicon deposition; a feed pipe (20) that forms a feed channel for feeding the raw material gas (G1) into the reactor (10), the feed pipe (20) including an inflow port (111) which is formed in the reactor (10) and through which the raw material gas (G1) flows in; and a filter (30) for removing impurities which have mixed in the raw material gas (G1), the filter (30) being provided in the feed channel.

The present disclosure relates to systems and methods for reducing the formation of hardware residue and minimizing secondary plasma formation during substrate processing in a process chamber. The process chamber may include a gas distribution member configured to flow a first gas into a process volume and generate a plasma therefrom. A second gas is supplied into a lower region of the process volume. Further, an exhaust port is disposed in the lower region to remove excess gases or by-products from the process volume during or after processing.

The present disclosure relates to a plasma resistant member in which a surface exposed to plasma is formed from a single crystal yttrium⋅aluminum⋅garnet (YAG) having a {100} plane, and a plasma treatment device component and a plasma treatment device using the plasma resistant member. When there are a plurality of surfaces exposed to plasma, at least a surface required to have the highest plasma resistance is formed from the single crystal YAG having a {100} plane.

Described herein is a technique capable of properly attaching a nozzle to a reaction tube. According to one aspect thereof, there is provided a nozzle installation jig including: a lower plate configured to make contact with a process vessel in a vicinity of a lower end opening of the process vessel in which a nozzle is provided; a frame fixed to the lower plate and extending upward with respect to the lower plate; an upper plate fixed to the frame and provided with a sensor configured to detect a position of the nozzle in the process vessel; and a notification device configured to transmit a notification to an operator according to a detection result of the sensor.

Provided is a SiC chemical vapor deposition apparatus including: a furnace body inside of which a growth space is formed; and a placement table which is positioned in the growth space and has a placement surface on which a SiC wafer is placed, in which the furnace body comprises a first hole which is positioned on an upper portion which faces the placement surface and through which a raw material gas is introduced into the growth space, a second hole which is positioned on a side wall of the furnace body and through which a purge gas flows into the growth space, a third hole which is positioned on the side wall of the furnace body at a lower position than the second hole and discharges the gases in the growth space, and a protrusion which is protrudes towards the growth space from a lower end of the second hole to adjust a flow of the raw material gas.

One or more embodiments described herein generally relate to methods and systems for forming films on substrates in semiconductor processes. In embodiments described herein, process chamber is provided that includes a lid plate having a plurality of cooling channels formed therein, a pedestal, the pedestal having a plurality of cooling channels formed therein, and a showerhead, wherein the showerhead comprises a plurality of segments and each segment is at least partially surrounded by a shield.