A processing apparatus is provided. The processing apparatus includes a processing chamber, a pump, and an intersecting module. The process chamber has a gas outlet. The pump communicates with the gas outlet. The pump is configured to exhaust gas from the processing chamber via the gas outlet. The intersecting module is positioned between the pump and the gas outlet. The intersecting module includes a plurality of support members and a plurality of internal ventilating plates. The support members are arranged along a longitudinal direction. Each of the internal ventilating plates has a plurality of orifices. At least one of the internal ventilating plates is positioned between two of the support members positioned adjacent to each other in the longitudinal direction. Each of the internal ventilating plates is inclined relative to a transversal direction that is perpendicular to the longitudinal direction.

Apparatus for atomic layer deposition on a surface of a substrate includes a precursor injector head. The precursor injector head includes a precursor supply and a deposition space that in use is bounded by the precursor injector head and the substrate surface. The precursor injector head is arranged for injecting a precursor gas from the precursor supply into the deposition space for contacting the substrate surface. The apparatus is arranged for relative motion between the deposition space and the substrate in a plane of the substrate surface. The apparatus is provided with a confining structure arranged for confining the injected precursor gas to the deposition space adjacent to the substrate surface.

An apparatus for forming semiconductor films can include a horizontal flow reactor including an upper portion and a lower portion that are moveably coupled to one another so as to separate from one another in an open position and so as to mate together in a closed position to form a reactor chamber. A central injector column can penetrate through the upper portion of the horizontal flow reactor into the reactor chamber, the central injector column configured to allow metalorganic precursors into the reactor chamber in the closed position. A heated metalorganic precursor line can be coupled to the central injector column and configured to heat a low vapor pressure metalorganic precursor vapor contained in the heated metalorganic precursor line upstream of the central injector column to a temperature range between about 70° C. and 200° C.

A shower plate that includes a plate-like member provided at a top of a processing chamber is provided. The shower plate has first holes communicating with a first flow path in the shower plate. The shower plate includes first chamber valves provided with the respective first holes. The shower plate has second holes communicating with a second flow path in the shower plate. The shower plate includes second chamber valves provided with the respective second holes. The shower plate has third holes provided in the plate-like member to correspond to the first holes and the second holes. The shower plate includes third chamber valves provided with the respective third holes. The first chamber valves, the second chamber valves, and the third chamber valves are piezoelectric elements.

Methods and apparatus for self-assembled monolayer (SAM) deposition are provided herein. In some embodiments, an apparatus for self-assembled monolayer (SAM) deposition includes: a chamber enclosing a processing volume; a substrate support disposed in the chamber and configured to support a substrate in the processing volume; a gas distribution system coupled to the chamber and configured to distribute a process gas into the processing volume; a first SAM precursor source fluidly coupled to the gas distribution system to provide a first SAM precursor as a part of the process gas; and a second SAM precursor source fluidly coupled to the gas distribution system to provide a second SAM precursor, different than the first SAM precursor, as a part of the process gas, wherein the first and second SAM precursor sources are independently controllable to control a relative percentage of the first and second SAM precursors in the process gas with respect to each other.

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.

When a gas supplied to a gas injection unit is switched from a first processing gas to a second processing gas, a controller of a gas supply system performs control to open a first supply on/off valve connected to the gas injection unit and provided in a first gas supply line for supplying the first processing gas and a second exhaust on/off valve provided in a first gas exhaust line branched from the first gas supply line, close a second supply on/off valve connected to the gas injection unit and provided in a second gas supply line for supplying the second processing gas and a first exhaust on/off valve provided in a second gas exhaust line branched from the second gas supply line; and then open the second supply on/off valve and the first exhaust on/off valve and close the first supply on/off valve and the second exhaust on/off valve.

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.

A film forming apparatus comprises: a processing chamber in which a substrate is accommodated; a gas supply configured to supply a gas containing a first monomer and a gas containing a second monomer into the processing chamber; a concentration distribution controller configured to control a gas flow within the processing chamber such that a concentration of a mixed gas including the gas containing the first monomer and the gas containing the second monomer on the substrate has a predetermined distribution; and a temperature distribution controller configured to control a temperature distribution of the substrate such that a temperature of a first region of the substrate is higher than a temperature of a second region of the substrate, the concentration of the mixed gas in a region corresponding to the first region being higher than the concentration of the mixed gas in a region corresponding to the second region.

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.