A method of forming an integrated circuit using an amorphous carbon film. The amorphous carbon film is formed by thermally decomposing a gas mixture comprising a hydrocarbon compound and an inert gas. The amorphous carbon film is compatible with integrated circuit fabrication processes. In one integrated circuit fabrication process, the amorphous carbon film is used as a hardmask. In another integrated circuit fabrication process, the amorphous carbon film is an anti-reflective coating (ARC) for deep ultraviolet (DUV) lithography. In yet another integrated circuit fabrication process, a multi-layer amorphous carbon anti-reflective coating is used for DUV lithography.

Method of depositing an amorphous carbon layer

Methods for preparing organic thin films on substrates, the method comprising the steps of providing a plurality of organic precursors in the vapor phase, and reacting the plurality or organic precursors at a sub-atmospheric pressure. Also included are thin films made by such a method and apparatuses used to conduct such a method. The method is well-suited to the formation of organic light emitting devices and other display-related technologies.

Low pressure vapor phase deposition of organic thin films

An apparatus and method for performing a cyclical layer deposition process, such as atomic layer deposition is provided. In one aspect, the apparatus includes a substrate support having a substrate receiving surface, and a chamber lid comprising a tapered passageway extending from a central portion of the chamber lid and a bottom surface extending from the passageway to a peripheral portion of the chamber lid, the bottom surface shaped and sized to substantially cover the substrate receiving surface. The apparatus also includes one or more valves coupled to the gradually expanding channel, and one or more gas sources coupled to each valve.

Gas delivery apparatus for atomic layer deposition

Embodiments of the invention provide an apparatus configured to form a material during an atomic layer deposition (ALD) process, such as a plasma-enhanced ALD (PE-ALD) process. In one embodiment, a lid assembly for conducting a vapor deposition process within a process chamber is provided which includes an insulation cap and a plasma screen. In one example, the insulation cap has a centralized channel configured to flow a first process gas from an upper surface to an expanded channel and an outer channel configured to flow a second process gas from an upper surface to a groove which is encircling the expanded channel. In one example, the plasma screen has an upper surface containing an inner area with a plurality of holes and an outer area with a plurality of slots. The insulation cap may be positioned on top of the plasma screen to form a centralized gas region with the expanded channel and a circular gas region with the groove.

Apparatus and process for plasma-enhanced atomic layer deposition

One embodiment of the gas delivery assembly comprises a covering member having an expanding channel at a central portion of the covering member and having a bottom surface extending from the expanding channel to a peripheral portion of the covering member. One or more gas conduits are coupled to the expanding channel in which the one or more gas conduits are positioned at an angle from a center of the expanding channel. One embodiment of a chamber comprises a substrate support having a substrate receiving surface. The chamber further includes a chamber lid having a passageway at a central portion of the chamber lid and a tapered bottom surface extending from the passageway to a peripheral portion of the chamber lid. The bottom surface of the chamber lid is shaped and sized to substantially cover the substrate receiving surface. One or more valves are coupled to the passageway, and one or more gas sources are coupled to each valve. In one aspect, the bottom surface of the chamber lid may be tapered. In another aspect, a reaction zone defined between the chamber lid and the substrate receiving surface may comprise a small volume. In still another aspect, the passageway may comprise a tapered expanding channel extending from the central portion of the chamber lid. Another embodiment of the chamber comprises a substrate support having a substrate receiving surface. The chamber further comprises a chamber lid having an expanding channel extending from a central portion of the chamber lid and having a tapered bottom surface extending from the expanding channel to a peripheral portion of the chamber lid. One or more gas conduits are disposed around an upper portion of the expanding channel in which the one or more gas conduits are disposed at an angle from a center of the expanding channel. A choke is disposed on the chamber lid adjacent a perimeter of the tapered bottom surface.

Gas delivery apparatus and method for atomic layer deposition

A refractory metal layer is deposited onto a substrate having high aspect ratio contracts or vias formed thereon. Next, a plasma-enhanced CVD refractory metal nitride layer is deposited on the refractory metal layer. Then, a metal layer is deposited over the metal nitride layer. The resulting metal layer is substantially void free and has reduced resistivity, and has greater effective line width. Plasma-enhanced chemical vapor deposition of the metal nitride layer comprises forming a plasma of a metal-containing compound, a nitrogen-containing gas, and a hydrogen-gas to deposit a metal nitride layer on a substrate. The metal nitride layer is preferably treated with nitrogen plasma to densify the metal nitride film. The process is preferably carried out in an integrated processing system that generally includes various chambers so that once the substrate is introduced into a vacuum environment, the metallization of the vias and contacts occurs without exposure to possible contaminants.

Plasma-enhanced chemical vapor deposition of a metal nitride layer

The present invention generally provides a metallization process for forming a highly integrated interconnect. More particularly, the present invention provides a dual darmascene interconnect module that incorporates a barrier layer (54) deposited on all exposed surface of a dielectric layer which contains a dual damascene via and wire definition (48, 50). A conductive metal (60, 62) is deposited on the barrier layer using two or more deposition methods to fill the via (48) and wire (50) definition prior to planarization.

Dual damascene metallization

Embodiments described herein provide a method for forming two titanium nitride materials by different PVD processes, such that a metallic titanium nitride layer is initially formed by a PVD process in a metallic mode and a titanium nitride retarding layer is formed over a portion of the metallic titanium nitride layer by a PVD process in a poison mode. Subsequently, a first aluminum layer, such as an aluminum seed layer, may be selectively deposited on exposed portions of the metallic titanium nitride layer by a CVD process. Thereafter, a second aluminum layer, such as an aluminum bulk layer, may be deposited on exposed portions of the first aluminum layer and the titanium nitride retarding layer during an aluminum PVD process.

Deposition processes for titanium nitride barrier and aluminum

Blocker plates for chemical vapor deposition chambers and methods of treating blocker plates are provided. The blocker plates define a plurality of holes therethrough and have an upper surface and a lower surface that at least about 99.5% pure, which minimizes the nucleation of contaminating particles on the blocker plates. A physically vapor deposited coating, such as an aluminum physically vapor deposited coating, may be formed on the upper and lower surfaces of the blocker plates. Chemical vapor deposition chambers including blocker plates having a physically vapor deposited coating thereon are also provided.

Unique passivation technique for a cvd blocker plate to prevent particle formation

The present invention relates generally to an improved process for providing complete via fill on a substrate and planarization of metal layers to form continuous, void-free contacts or vias in sub-half micron applications. In one aspect of the invention, a refractory layer is deposited onto a substrate having high aspect ratio contacts or vias formed thereon. A CVD metal layer, such as CVD Al or CVD Cu, is then deposited onto the refractory layer at low temperatures to provide a conformal wetting layer for a PVD Cu. Next, a PVD Cu is deposited onto the previously formed CVD Cu layer at a temperature below that of the melting point temperature of the metal. The resulting CVD/PVD Cu layer is substantially void-free. The metallization process is preferably carried out in an integrated processing system that includes both a PVD and CVD processing chamber so that once the substrate is introduced into a vacuum environment, the metallization of the vias and contacts occurs without the formation of an oxide layer over the CVD Cu layer. The via fill process of the present invention is also successful with air-exposure between the CVD Cu and PVD Cu steps.

Low temperature integrated via and trench fill process and apparatus

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