Abstract: A method of forming a boride layer for integrated circuit fabrication is disclosed. In one embodiment, the boride layer is formed by chemisorbing monolayers of a boron-containing compound and one refractory metal compound onto a substrate. In an alternate embodiment, the boride layer has a composite structure. The composite boride layer structure comprises two or more refractory metals. The composite boride layer is formed by sequentially chemisorbing monolayers of a boron compound and two or more refractory metal compounds on a substrate.

Abstract: A method of forming a boride layer for integrated circuit fabrication is disclosed. In one embodiment, the boride layer is formed by chemisorbing monolayers of a boron-containing compound and one refractory metal compound onto a substrate. In an alternate embodiment, the boride layer has a composite structure. The composite boride layer structure comprises two or more refractory metals. The composite boride layer is formed by sequentially chemisorbing monolayers of a boron compound and two or more refractory metal compounds on a substrate.

Abstract: Methods of depositing titanium nitride (TiN) films on a substrate are disclosed. The titanium nitride (TiN) films may be formed using a cyclical deposition process by alternately adsorbing a titanium-containing precursor and a NH3 gas on the substrate. The titanium-containing precursor and the NH3 gas react to form the titanium nitride (TiN) layer on the substrate. The titanium nitride (TiN) films are compatible with integrated circuit fabrication processes. In one integrated circuit fabrication process, an interconnect structure is fabricated. The titanium nitride films may also be used as an electrode of a three-dimensional capacitor structure such as for example, trench capacitors and crown capacitors.

Abstract: Methods for the deposition of tungsten films are provided. The methods include depositing a nucleation layer by alternatively adsorbing a tungsten precursor and a reducing gas on a substrate, and depositing a bulk layer of tungsten over the nucleation layer.

Abstract: A process for treating refractory metal-boron layers deposited by atomic layer deposition resulting in the formation of a ternary amorphous refractory metal-nitrogen-boron film is disclosed. The resulting ternary film remains amorphous following thermal annealing at temperatures up to 800° C. The ternary films are formed following thermal annealing in a reactive nitrogen-containing gas. Subsequent processing does not disrupt the amorphous character of the ternary film. arrangement where a blended solution is supplied to a remote point of use.

Abstract: A method of forming a boride layer for integrated circuit fabrication is disclosed. In one embodiment, the boride layer is formed by chemisorbing monolayers of a boron containing compound and one refractory metal compound onto a substrate. In an alternate embodiment, the boride layer has a composite structure. The composite boride layer structure comprises two or more refractory metals. The composite boride layer is formed by sequentially chemisorbing monolayers of a boron compound and two or more refractory metal compounds on a substrate.

Abstract: A method and system to form a refractory metal layer on a substrate features a bifurcated deposition process that includes nucleating a substrate using ALD techniques to serially expose the substrate to first and second reactive gases followed forming a bulk layer, adjacent to the nucleating layer, using CVD techniques to concurrently exposing the nucleation layer to the first and second gases.

Abstract: A method of forming a film structure (e.g., film stacks) comprising titanium (Ti) and/or titanium nitride (TiN). The Ti film structure is formed by alternately depositing and then plasma treating thin films (less than about 100 Å thick) of titanium. The TiN film structure is formed by alternately depositing and then plasma treating thin films (less than about 300 Å thick) of titanium nitride. The titanium films are formed using a plasma reaction of titanium tetrachloride (TiCl4) and a hydrogen-containing gas. The titanium nitride films are formed by thermally reacting titanium tetrachloride with a nitrogen-containing gas. The subsequent plasma treatment steps comprise a nitrogen/hydrogen-containing plasma.

Abstract: A method and apparatus for forming a metal interconnect is provided. A tungsten plug is first deposited by selective WCVD within a feature having an aspect ratio of 3:1 or greater to at least partially fill the feature. An IMP barrier layer is next deposited over the tungsten plug. A PVD copper seed layer followed by an ECP copper layer is then deposited over the barrier layer to fill the feature. The tungsten plug has a thickness of about 1,000 to about 5,000 angstroms and fills less than about 50% of the volume of the feature.

Abstract: Refractory metal nitride layers for integrated circuit fabrication are described. The refractory metal nitride layer may be formed by sequentially chemisorbing alternating monolayers of a nitrogen-containing compound and a refractory metal compound onto a substrate. A composite refractory metal nitride layer is also described. The composite refractory metal nitride layer may be formed by sequentially chemisorbing monolayers of a nitrogen-containing compound and two or more refractory metal compounds onto a substrate.

Abstract: A method and apparatus for atomic layer deposition (ALD) is described. The apparatus comprises a deposition chamber and a wafer support. The deposition chamber is divided into two or more deposition regions that are integrally connected one to another. The wafer support is movable between the two or more interconnected deposition regions within the deposition chamber.

Abstract: A method and system to form a refractory metal layer over a substrate includes introduction of a reductant, such as PH3 or B2H6, followed by introduction of a tungsten containing compound, such as WF6, to form a tungsten layer. It is believed that the reductant reduces the fluorine content of the tungsten layer while improving the step coverage and resistivity of the tungsten layer. It is believed that the improved characteristics of the tungsten film are attributable to the chemical affinity between the reductants and the tungsten containing compound. The chemical affinity provides better surface mobility of the adsorbed chemical species and better reduction of WF6 at the nucleation stage of the tungsten layer. The method can further include sequentially introducing a reductant, such as PH3 or B2H6, and a tungsten containing compound to deposit a tungsten layer. The formed tungsten layer can be used as a nucleation layer followed by bulk deposition of a tungsten layer utilizing standard CVD techniques.

Abstract: A system and method to form a stacked barrier layer for copper contacts formed on a substrate. The substrate is serially exposed to first and second reactive gases to form an adhesion layer. Then, the adhesion layer is serially exposed to third and fourth reactive gases to form a barrier layer adjacent to the adhesion layer. This is followed by deposition of a copper layer adjacent to the barrier layer.

Abstract: A method of forming a refractory metal nitride layer for integrated circuit fabrication is disclosed. In one embodiment, the refractory metal nitride layer is formed by chemisorbing monolayers of a hydrazine-based compound and one or more refractory metal compounds onto a substrate. In an alternate embodiment, the refractory metal nitride layer has a composite structure, which is composed of two or more refractory metals. The composite refractory metal nitride layer is formed by sequentially chemisorbing monolayers of a hydrazine-based compound and two or more refractory metal compounds on a substrate.

Abstract: A method for fabricating a semiconductor device improves step coverage and resistivity. The method includes the steps of forming a doped silicon layer on a substrate, forming a silicide layer containing more metal atoms than silicon atoms on the doped silicon layer, and heat treating in nitrogen to form a second silicide layer having a tetragonal phase crystal structure and a silicon nitride film on the top surface of the second silicide layer.

Abstract: An electrode passivation layer of a semiconductor device and a method for forming the same having improved corrosion-resistance and oxidation-resistance are disclosed, the electrode passivation film including a semiconductor substrate; a conductive layer pattern formed on the semiconductor substrate; and an amorphous passivation film formed on the conductive layer pattern.

Abstract: Method for fabricating a semiconductor device, is disclosed, which is suitable for improving a resistivity, including the steps of forming a silicon layer on a substrate, forming a crystalline metal silicide layer on the silicon layer, forming an amorphous metal silicide layer by injecting ions into the crystalline metal silicide layer, and crystallizing the amorphous metal silicide by heat treating the amorphous metal silicide.

Abstract: The present invention relates to forming epitaxial Co self-align silicide for a semiconductor device. An epitaxial Co self-align suicide layer for a semiconductor device is formed by forming a buffer layer on a silicon substrate, depositing cobalt thereon and applying an annealing process thereto to restrain silicon and cobalt from radically reacting on each other when applying the annealing process after depositing cobalt on the silicon substrate. The buffer layer is formed by performing a surface treatment using CHF.sub.3 or O.sub.2 onto the silicon substrate, applying an ion implantation using carbon, fluorine or oxygen to the silicon substrate, or exposing the silicon substrate to oxygen plasma. The present invention has an effect of forming shallow junction for a scaling down process to improve the integration of the semiconductor device.

Abstract: A method for forming a silicide layer in a semiconductor device, including the steps of: forming a refractory metal layer on a semiconductor substrate; forming a cobalt layer on the refractory metal layer; implanting impurities in the interface between the refractory metal layer and the cobalt layer; heat treating the semiconductor substrate such that cobalt atoms from the cobalt layer pass through the refractory metal layer and form a cobalt silicide epitaxy layer on the semiconductor substrate; and removing the remaining cobalt layer and the remaining refractory metal layer.

Abstract: A method of forming an electrode of a semiconductor device includes the steps of forming an insulating layer on a semiconductor substrate, forming a tungsten silicide layer on the insulating layer, implanting impurity ions into the tungsten silicide layer to form an impurity region in a lower portion of the tungsten silicide layer, and carrying out a heat treatment to the substrate on which the tungsten silicide layer is formed.