There is provided a substrate processing apparatus that includes a process chamber in which at least one substrate is processed; a gas supplier configured to supply a gas; and a buffer structure. The buffer structure includes at least two plasma generation regions in which gas is converted into plasma by a pair of electrodes connected to a high-frequency power supply and an electrode to be grounded, a first gas supply port that supplies a gas generated in a first plasma generation region among the at least two plasma generation regions, and a second gas supply port that supplies a gas generated in a second plasma generation region among the at least two plasma generation regions.

The present disclosure provides a technique that includes: loading a substrate into a process chamber in which the substrate is processed; and processing the substrate by supplying a first inert gas to a peripheral portion of the substrate and simultaneously supplying a mixed gas of a second inert gas different from the first inert gas and a process gas to a surface of the substrate.

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.

A device for manufacturing a semiconductor device is provided. The device for manufacturing a semiconductor device includes a tube extending in a first direction, and defining a reaction space therein and configured to accommodate a boat that is configured to receive a plurality of substrates therein, and first and second nozzles each extending in the first direction inside the tube, and being apart from each other on a plane that is perpendicular to the first direction and parallel to upper surfaces of the substrates, wherein the first and second nozzles include a plurality of first injection ports and a plurality of first second injection ports that are configured inject different gases toward a center of the reaction space, respectively, and a plurality of second injection ports are placed in a region between a corresponding pair of adjacent ones of the plurality of first injection ports along the first direction.

A component, a method of manufacturing a component, and a method of cleaning a component is provided. The component includes a gas flow system within the component, wherein the gas flow system fluidly couples one or more inlet holes and one or more outlet holes. The manufacturing of the component results in an arc shaped groove and a circumferential groove created in the body of the ring. The component undergoes one or more cleaning operations, including rinsing, baking, or purging operations. The cleaning operations remove debris or particles in or on the component, where the debris or particles can be caused during manufacturing of the component, or during use of the component in a semiconductor processing system.

A plasma processing apparatus includes: a processing container having a cylindrical shape; a pair of plasma electrodes arranged along the longitudinal direction of the processing container while facing each other; and a radio-frequency power supply configured to supply a radio-frequency power to the pair of plasma electrodes. In the pair of plasma electrodes, an inter-electrode distance at a position distant from a power feed position to which the radio-frequency power is supplied is longer than an inter-electrode distance at the power feed position.

A chemical vapor deposition furnace for depositing silicon nitride films, is discloses. The furnace comprising a process chamber elongated in a substantially vertical direction and a wafer boat for supporting a plurality of wafers in the process chamber. A process gas injector is provided inside the process chamber extending in a substantially vertical direction over substantially a wafer boat height and comprising a feed end connected to a source of a silicon precursor and a source of a nitrogen precursor and a plurality of vertically spaced gas injection holes to provide gas from the feed end to the process chamber. The furnace may comprise a purge gas injection system to provide a purge gas into the process chamber near a lower end of the process chamber.

A semiconductor processing apparatus includes an outer tube, an inner tube in the outer tube and providing a process space, and a nozzle between the outer tube and the inner tube. The nozzle provides an internal passage. The inner tube provides a slit. The nozzle provides a plurality of holes. The plurality of holes are vertically spaced apart from each other. The slit vertically extends to expose at least two of the plurality of holes. The internal passage is connected to the process space through the slit and the plurality of holes.

Described herein is a technique capable of improving the uniformity of the film formation among the substrates. According to the technique described herein, there is provided a configuration including: a reaction tube having a process chamber where a plurality of substrates are processed; a buffer chamber protruding outward from the reaction tube and configured to supply a process gas to the process chamber, the buffer chamber including: a first nozzle chamber where a first nozzle is provided; and a second nozzle chamber where a second nozzle is provided; an opening portion provided at a lower end of an inner wall of the reaction tube facing the buffer chamber; and a shielding portion provided at a communicating portion of the opening portion between the second nozzle chamber and the process chamber.

A coated cutting tool includes a substrate and a hard film on coated on the substrate. The hard film contains a complex nitride of Al and Cr. The hard film includes aggregates of columnar grains grown on the substrate along the thickness of the film. The nitride has an Al content of 60 atom % or more, a Cr content of 10 atom % or more, and a total content of Al and Cr of 90 atom % or more relative to the total amount of metal and metalloid elements. The complex nitride has the highest peak intensity assigned to crystal plane (311) of an fcc structure in X-ray diffractometry. In the hard film, the ratio of an X-ray diffraction intensity of plane (311) to the intensities of the other planes is 1.30 or more. A method and a system are also provided for manufacturing the coated cutting tool by chemical vapor deposition.