Abstract: A plasma generating system generates plasma in a processing chamber. A controller is configured to: a) perform atomic layer deposition (ALD) N times to deposit film in a feature of the substrate; b) after performing a) M of the N times, supply an inhibitor plasma gas to the processing chamber and strike plasma in the processing chamber to create a passivated surface more on upper portions of the feature as compared to lower portions of the feature to inhibit the atomic layer deposition in the upper portions of the feature as compared to the lower portions of the feature; c) supply an etch gas to the processing chamber to etch the film more in the upper portions of the feature than in the lower portions in the feature of the substrate following b); and d) repeat a) to c) one or more times to gapfill the feature without voids.

Abstract: A method for performing gapfill of features of a substrate including a) arranging a substrate on a substrate support in a processing chamber; b) performing atomic layer deposition (ALD) to deposit film in a feature of the substrate; c) supplying an inhibitor plasma gas to the processing chamber and striking plasma in the processing chamber to inhibit deposition in upper portions of the feature as compared to lower portions of the feature; d) repeating b) N times, where N is an integer greater than one, and repeating c) M of the N times where M is an integer greater than zero and less than or equal to N; e) supplying an etch gas to the processing chamber to etch the film in the feature of the substrate; and f) repeating b) to e) one or more times to gapfill the feature of the substrate.

Abstract: A method for performing gapfill of features of a substrate including a) arranging a substrate on a substrate support in a processing chamber; b) performing atomic layer deposition (ALD) to deposit film in a feature of the substrate; c) supplying an inhibitor plasma gas to the processing chamber and striking plasma in the processing chamber to inhibit deposition in upper portions of the feature as compared to lower portions of the feature; d) repeating b) N times, where N is an integer greater than one, and repeating c) M of the N times where M is an integer greater than zero and less than or equal to N; e) supplying an etch gas to the processing chamber to etch the film in the feature of the substrate; and f) repeating b) to d) one or more times to gapfill the feature of the substrate.

Abstract: A semiconductor substrate processing apparatus for processing semiconductor substrates includes showerhead module delivering process gas through a faceplate having gas passages therethrough from the process gas source to a processing zone of the processing apparatus wherein individual semiconductor substrates are processed. The showerhead module comprises a gas delivery conduit in fluid communication with a cavity at a lower end thereof, a baffle arrangement in the gas delivery conduit and the cavity, and a blocker plate in the cavity disposed below the baffle arrangement. The baffle arrangement comprises baffles which divide process gas flowing through the gas delivery conduit into center, inner annular, and outer annular flow streams.

Abstract: A method for processing a substrate to create an air gap includes a) providing a substrate including a first trench and a second trench; b) depositing a conformal layer on the substrate; c) performing sputtering to at least partially pinch off an upper portion of the first trench and the second trench at a location spaced from upper openings of the first trench and the second trench; and d) performing sputtering/deposition to seal first and second airgaps in the first trench and the second trench.

Abstract: An apparatus for transporting or storing at least one semiconductor wafer in an ultra-high vacuum is provided. A portable vacuum transfer pod is provided comprising an internal wafer storage chamber for storing one or more wafers and a wafer support for supporting at least one wafer within the internal wafer storage chamber. A passively capable vacuum pump capable of passive vacuum pumping is in fluid connection with the internal wafer storage chamber and is mechanically connected to the portable vacuum transfer pod. A shut off valve for opening and closing the fluid connection is between the passively capable vacuum pump and the internal wafer storage chamber.

Abstract: Methods of depositing a film on a substrate surface include surface mediated reactions in which a film is grown over one or more cycles of reactant adsorption and reaction. In one aspect, the method is characterized by intermittent delivery of dopant species to the film between the cycles of adsorption and reaction.

Abstract: Treatment of carbon-containing low-k dielectric with UV radiation and a reducing agent enables process-induced damage repair. Also, treatment with a reducing agent and UV radiation is effective to clean a processed wafer surface by removal of metal oxide (e.g., copper oxide) and/or organic residue of CMP slurry from the planarized surface of a processed wafer with or without low-k dielectric. The methods of the invention are particularly applicable in the context of damascene processing to recover lost low-k property of a dielectric damaged during processing, either pre-metalization, post-planarization, or both, and/or provide effective post-planarization surface cleaning to improve adhesion of subsequently applied dielectric barrier and/or other layers.

Abstract: Systems and methods for depositing film in a substrate processing system includes performing a first atomic layer deposition (ALD) cycle in a processing chamber to deposit film on a substrate including a feature; after the first ALD cycle, exposing the substrate to an inhibitor plasma in the processing chamber for a predetermined period to create a varying passivated surface in the feature; and after the predetermined period, performing a second ALD cycle in the processing chamber to deposit film on the substrate.

Abstract: Methods of densifying films, cross-linking films, and controlling the stress of films are provided herein. Methods include forming a removable film on a substrate comprising a material to be densified, and annealing the substrate to transfer stress from the removable film to the material and thereby densify the material. Some methods involve depositing a tensile capping layer on the material to be densified on a substrate and annealing the substrate at a temperature greater than about 450° C. Some methods include clamping the substrate including the material to be densified to a shaped pedestal using an electrostatic chuck to apply compressive stress to the material to be densified.

Abstract: A method for densifying a dielectric film on a substrate includes arranging a substrate including a dielectric film on a substrate support in a substrate processing chamber; supplying a gas mixture including helium and oxygen to the substrate processing chamber; controlling pressure in the substrate processing chamber to a pressure greater than or equal to a predetermined pressure; supplying a first power level at a first frequency to a coil to create plasma in the substrate processing chamber. The coil is arranged around an outer surface of the substrate processing chamber. The method includes densifying the dielectric film for a predetermined period. The pressure and the first power level are selected to prevent sputtering of the dielectric film during densification of the dielectric film.

Abstract: A method for processing a substrate to create an air gap includes a) providing a substrate including a first trench and a second trench; b) depositing a conformal layer on the substrate; c) performing sputtering to at least partially pinch off an upper portion of the first trench and the second trench at a location spaced from upper openings of the first trench and the second trench; and d) performing sputtering/deposition to seal first and second airgaps in the first trench and the second trench.

Abstract: Described are methods of making silicon nitride (SiN) materials on substrates. Improved SiN films made by the methods are also included. One aspect relates to depositing chlorine (Cl)-free conformal SiN films. In some embodiments, the SiN films are Cl-free and carbon (C)-free. Another aspect relates to methods of tuning the stress and/or wet etch rate of conformal SiN films. Another aspect relates to low-temperature methods of depositing high quality conformal SiN films. In some embodiments, the methods involve using trisilylamine (TSA) as a silicon-containing precursor.

Abstract: Methods of depositing a film on a substrate surface include surface mediated reactions in which a film is grown over one or more cycles of reactant adsorption and reaction. In one aspect, the method is characterized by intermittent delivery of dopant species to the film between the cycles of adsorption and reaction.

Abstract: Methods of densifying films, cross-linking films, and controlling the stress of films are provided herein. Methods include forming a removable film on a substrate comprising a material to be densified, and annealing the substrate to transfer stress from the removable film to the material and thereby densify the material. Some methods involve depositing a tensile capping layer on the material to be densified on a substrate and annealing the substrate at a temperature greater than about 450° C. Some methods include clamping the substrate including the material to be densified to a shaped pedestal using an electrostatic chuck to apply compressive stress to the material to be densified.

Abstract: Methods of depositing a film on a substrate surface include surface mediated reactions in which a film is grown over one or more cycles of reactant adsorption and reaction. In one aspect, the method is characterized by intermittent delivery of dopant species to the film between the cycles of adsorption and reaction.

Abstract: A method for providing a FinFET device with an air gap spacer includes providing a substrate a plurality of fins and a dummy gate arranged transverse to the plurality of fins; depositing a sacrificial spacer around the dummy gate; depositing a first interlayer dielectric (ILD) layer around the sacrificial spacer; selectively etching the dummy polysilicon gate relative to the first ILD layer and the sacrificial spacer; depositing a replacement metal gate (RMG); etching a portion of the RMG to create a recess surrounded by the sacrificial spacer; and depositing a gate capping layer in the recess. The gate capping layer is at least partially surrounded by the sacrificial spacer and is made of silicon oxycarbide (SiOC).

Abstract: Systems and methods for depositing film in a substrate processing system includes performing a first atomic layer deposition (ALD) cycle in a processing chamber to deposit film on a substrate including a feature; after the first ALD cycle, exposing the substrate to an inhibitor plasma in the processing chamber for a predetermined period to create a varying passivated surface in the feature; and after the predetermined period, performing a second ALD cycle in the processing chamber to deposit film on the substrate.

Abstract: A dual-plenum showerhead for semiconductor processing operations is provided. The showerhead may include a faceplate with two sets of gas distribution holes, each set fed by a separate plenum. One set of gas distribution holes may be through-holes in the faceplate of the showerhead and may allow gases trapped between the faceplate and a plasma dome to flow towards a wafer. The other set of gas distribution holes may distribute gas routed through passages or channels in the faceplate towards the wafer. The passages or channels in the faceplate may include radial channels and annular channels and may be fed from an annular gas distribution channel about the periphery of the faceplate.

Abstract: Systems and methods for depositing film in a substrate processing system includes performing a first atomic layer deposition (ALD) cycle in a processing chamber to deposit film on a substrate including a feature; after the first ALD cycle, exposing the substrate to an inhibitor plasma in the processing chamber for a predetermined period to create a varying passivated surface in the feature; and after the predetermined period, performing a second ALD cycle in the processing chamber to deposit film on the substrate.