A method for fabricating a semiconductor device by using a plasma-enhanced atomic layer deposition apparatus. A substrate comprising a silicon substrate and a first oxide layer is provided. A plurality of stacked structures are deposited on the substrate, which comprises a dielectric layer and a conductive layer. The stacked structures are etched to form trenches. A second oxide layer is deposited by using a plasma-enhanced atomic layer deposition apparatus that includes a chamber, an upper electrode, a lower electrode, and a three-dimensional rotation device. The upper electrode is connected to a first radio-frequency power device. The upper electrode is configured to generate a plasma. The lower electrode is connected to a second radio-frequency power device. The three-dimensional rotation device drives the substrate to rotate. A high resistance layer is deposited on the second oxide layer. A low resistance layer is deposited on the high resistance layer.

Embodiments of the present invention provide a plasma chamber design that allows extremely symmetrical electrical, thermal, and gas flow conductance through the chamber. By providing such symmetry, plasma formed within the chamber naturally has improved uniformity across the surface of a substrate disposed in a processing region of the chamber. Further, other chamber additions, such as providing the ability to manipulate the gap between upper and lower electrodes as well as between a gas inlet and a substrate being processed, allows better control of plasma processing and uniformity as compared to conventional systems.

Plasma source assemblies comprising an RF hot electrode having a body and at least one return electrode spaced from the RF hot electrode to provide a gap in which a plasma can be formed. An RF feed is connected to the RF hot electrode at a distance from the inner peripheral end of the RF hot electrode that is less than or equal to about 25% of the length of the RF hot electrode.

A substrate processing device with improved exhaust efficiency and process reproducibility includes: a plurality of reactors; a plurality of exhaust ports in communication with the plurality of reactors and symmetrically arranged with respect to the reactors, respectively; and a plurality of exhaust channels in communication with the plurality of exhaust ports, wherein each exhaust channel includes a plurality of exhaust channels including a first channel extending in the first direction and a second channel extending in a second direction different from the first direction, wherein the plurality of exhaust channels extend through components supporting at least a portion of the plurality of reactors.

A method for manufacturing a sputtering target with which an oxide semiconductor film with a small amount of defects can be formed is provided. Alternatively, an oxide semiconductor film with a small amount of defects is formed. A method for manufacturing a sputtering target is provided, which includes the steps of: forming a polycrystalline In-M-Zn oxide (M represents a metal chosen among aluminum, titanium, gallium, yttrium, zirconium, lanthanum, cesium, neodymium, and hafnium) powder by mixing, sintering, and grinding indium oxide, an oxide of the metal, and zinc oxide; forming a mixture by mixing the polycrystalline In-M-Zn oxide powder and a zinc oxide powder; forming a compact by compacting the mixture; and sintering the compact.

The present invention improves the in-plane uniformity of film formation via a plasma treatment. It is provided a plasma treatment device constituted so that process gas introduced between an electrode plate and a shower plate is exhausted toward a counter electrode through a plurality of small holes formed in the shower plate, the plasma treatment device comprising a diffuser plate having a plurality of small holes, the diffuser plate being arranged substantially parallel with the shower plate, wherein the process gas is introduced between the electrode plate and the diffuser plate, passes through the plural small holes of the diffuser plate, reaches the shower plate and flows out from the plural small holes of the shower plate toward the electrode plate, and wherein within the small holes formed in the diffuser plate and the small holes formed in the shower plate, the small holes formed in a plate which exists more downstream along a flowing direction of the process gas are made in smaller diameters and an aperture ratio of each plate is made smaller in a plate which exists more upstream along the flowing direction of the process gas.

The present disclosure provides a method to adjust asymmetric velocity of a scan in a scanning ion beam etch process to correct asymmetry of etching between the inboard side and the outboard side of device structures on a wafer, while maintaining the overall uniformity of etch across the full wafer.

A deposition chamber includes a vacuum enclosure, an electrostatic chuck having a flat top surface located within a vacuum enclosure, a lift-and-rotation unit extending through or laterally surrounding the electrostatic chuck at a position that is laterally offset from a vertical axis passing through a geometrical center of the electrostatic chuck, a gas supply manifold configured to provide influx of gas into the vacuum enclosure, and a pumping port connected to the vacuum enclosure.

An apparatus includes an electrostatic chuck and located within a vacuum enclosure. A plurality of conductive plates can be embedded in the electrostatic chuck, and a plurality of plate bias circuits can be configured to independently electrically bias a respective one of the plurality of conductive plates. Alternatively or additionally, a plurality of spot lamp zones including a respective set of spot lamps can be provided between a bottom portion of the vacuum enclosure and a backside surface of the electrostatic chuck. The plurality of conductive plates and/or the plurality of spot lamp zones can be employed to locally modify chucking force and to provide local temperature control.

In one embodiment, at least a processing chamber includes a perforated lid, a gas blocker disposed on the perforated lid, and a substrate support disposed below the perforated lid. The gas blocker includes a gas manifold, a central gas channel formed in the gas manifold, a first gas distribution plate comprising an inner and outer trenches surrounding the central gas channel, a first and second gas channels formed in the gas manifold, the first gas channel is in fluid communication with a first gas source and the inner trench, and the second gas channel is in fluid communication with the first gas source and the outer trench, a second gas distribution plate, a third gas distribution plate disposed below the second gas distribution plate, and a plurality of pass-through channels disposed between the second gas distribution plate and the third gas distribution plate. The second gas distribution plate includes a plurality of through holes formed through a bottom of the second gas distribution plate, a central opening in fluid communication with the central gas channel, and a recess region formed in a top surface of the second gas distribution plate, and the recess region surrounds the central opening.