A gas distribution device has a plurality of gas inlet regions that are arranged above each other and can be adjusted by switching on or off respective valves. The gas inlet regions can also be adjusted by switching over one or more feed conduits through which process gases can be fed into respective gas distribution volumes of gas outlet zones. The respective gas distribution volumes are arranged above each other at several levels. Only one uniform process gas can exit into a process chamber through each of the gas inlet regions.

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.

A gas inlet element for a CVD reactor includes a cylindrical main body, which together with an outer wall, forms a gas outlet face. The outer wall surrounds at least one gas distribution chamber. A plurality of gas outlet openings originating in the gas distribution chamber open out into the gas outlet face. A cooling device includes a plurality of cooling channels running adjacently but separately in the outer wall, and the gas outlet openings extend between the cooling channels.

Systems and apparatus for a reduced mass substrate support are disclosed, according to certain embodiments. A front side pocket is provided for support of a substrate, while a backside pocket is provided that reduces the mass of the substrate support. By providing the backside pocket, the mass of the overall substrate support is reduced, providing faster thermal cycling times for the substrate support and reducing the weight of the substrate support for transport. Lift pin systems, according to disclosed embodiments, are compatible with existing pedestal systems by providing a hollow extension from each lift pin hole that extends from a bottom of the backside pocket to provide support for lift pin insertion and operation.

A CVD apparatus for manufacturing a III-nitride-based layer having a rotating wafer carrier positioned inside a reaction chamber that receives a mixture of a nitrogen gas source and a group III element gas source. Recesses are formed within the wafer carrier, each including a satellite disc of thickness x for accepting a wafer of thickness t. The satellite disc includes a peripheral notch of height a, and a notch thickness of x−a=b. A peripheral retaining ring includes a vertical rise portion extending a distance of e+f and a laterally-extending portion, the laterally-extending portion engaging the satellite disc notch. A gap c is formed between the substrate and a surface of the satellite disc. The relationship of a+b+c+t=b+e+f is satisfied such that laminar flow occurs in the region of the retaining ring.

Methods for modulating local stress and overlay error of one or more patterning films may include modulating a gas flow profile of gases introduced into a chamber body, flowing gases within the chamber body toward a substrate, rotating the substrate, and unifying a center-to-edge temperature profile of the substrate by controlling the substrate temperature with a dual zone heater. A chamber for depositing a film may include a chamber body comprising one or more processing regions. The chamber body may include a gas distribution assembly having a blocker plate for delivering gases into the one or more processing regions. The blocker plate may have a first region and a second region, and the first region and second region each may have a plurality of holes. The chamber body may have a dual zone heater.

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.

The present invention relates to a gas distributing injector applied in MOCVD reactor. The gas distributing injector comprises at least one gas distributing layer for distributing different gases. The distributing layer is a single-layered structure. The distributing layer comprises a disk-shaped body, a plurality of first gas channels, a plurality of second gas channels, and a plurality of third gas channels. The first gas channels, the second gas channels, and the third gas channels are radially distributed on the same plane in the disk-shaped body. Different gases are distributed or fed into different gas channels (such as the first gas channels, the second gas channels, and the third gas channels) and transported by different gas channels. Through different gas channels, different gases are transversely injected into the MOCVD reactor on the same plane respectively. Therefore, the gas distributing injector of this invention can distribute different gases by a single-layered structure.

A cutting tool comprises a substrate and a coating layer provided on the substrate, the coating layer including a multilayer structure layer composed of a first unit layer and a second unit layer, and a lone layer, the lone layer including cubic Ti.sub.zAl.sub.1-zN crystal grains, an atomic ratio z of Ti in the Ti.sub.zAl.sub.1-zN being 0.4 or more and less than 0.55, the lone layer having a thickness with an average value of 2.5 nm or more and 10 nm or less, the multilayer structure layer having a thickness with an average value of 10 nm or more and 45 nm or less, one multilayer structure layer and one lone layer forming a repetitive unit having a thickness with an average value of 20 nm to 50 nm, a maximum value of 40 nm to 60 nm, and a minimum value of 10 nm to 30 nm.

The embodiments described herein generally relate to a substrate support assembly for use in a plasma processing chamber to provide non-uniform gas flow flowing between the substrate support assembly and sidewalls of the plasma processing chamber. In one embodiment, a substrate support assembly includes a substrate support assembly including a substrate support body defining at least a first side of the substrate support body, and a corner region and a center region formed in the first side of the substrate support body, wherein the corner region has a corner width that is smaller than a center width of the center region, the widths defined between a center axis and the first side of the substrate support body.