Abstract: A method to selectively deposit a barrier layer on dielectric material that surrounds one or more metal interconnects on a substrate is disclosed. The barrier layer is selectively deposited on the metal film using a cyclical deposition process including a predetermined number of deposition cycles followed by a purge step. Each deposition cycle comprises alternately adsorbing a refractory metal-containing precursor and a reducing gas on the dielectric material formed on the substrate in a process chamber.

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: Embodiments of the present invention generally relate to an apparatus and method of integration of titanium and titanium nitride layers. One embodiment includes providing one or more cycles of a first set of compounds, providing one or more cycles of a second set of compounds, and providing one or more cycles of a third set of compounds. One cycle of the first set of compounds includes introducing a titanium precursor and a reductant. One cycle of the second set of compounds includes introducing the titanium precursor and a silicon precursor. One cycle of the third set of compounds includes introducing the titanium precursor and a nitrogen precursor. Another embodiment includes depositing a titanium layer utilizing titanium halide. Then, a passivation layer is deposited over the titanium layer utilizing titanium halide. The passivation layer may comprise titanium silicide, titanium silicon nitride, and combinations thereof.

Abstract: A method for cleaning the electrical contact areas or substrate contact areas of an electrochemical plating contact ring is provided. Embodiments of the method include positioning a substrate on a substrate support member having one or more electrical contacts, chemically plating a metal layer on at least a portion of a surface of the substrate, removing the processed substrate from the support member, and cleaning the one or more electrical contacts with a vapor mixture comprising an alcohol. In another aspect, the method includes spraying the vapor mixture on the electrical contacts while rotating the substrate support member.

Abstract: A method for forming a tungsten layer on a substrate surface is provided. In one aspect, the method includes positioning the substrate surface in a processing chamber and exposing the substrate surface to a boride. A nucleation layer is then deposited on the substrate surface in the same processing chamber by alternately pulsing a tungsten-containing compound and a reducing gas selected from a group consisting of silane (SiH4), disilane (Si2H6), dichlorosilane (SiCl2H2), derivatives thereof, and combinations thereof. A tungsten bulk fill may then be deposited on the nucleation layer using cyclical deposition, chemical vapor deposition, or physical vapor deposition techniques.

Abstract: A method of forming a composite tungsten film on a substrate is described. The composite tungsten film comprises sequentially deposited tungsten nucleation layers and tungsten bulk layers. Each of the tungsten nucleation layers and the tungsten bulk layers have a thickness less than about 300 Å. The tungsten nucleation layers and the tungsten bulk layers are formed one over the other until a desired thickness for the composite tungsten film is achieved. The resulting composite tungsten film exhibits good film morphology. The tungsten nucleation layers may be formed using a cyclical deposition process by alternately adsorbing a tungsten-containing precursor and a reducing gas on the substrate. The tungsten bulk layers may be formed using a chemical vapor deposition (CVD) process by thermally decomposing a tungsten-containing precursor.

Abstract: A method to selectively deposit a barrier layer on a metal film formed on a substrate is disclosed. The barrier layer is selectively deposited on the metal film using a cyclical deposition process including a predetermined number of deposition cycles followed by a purge step. Each deposition cycle comprises alternately adsorbing a refractory metal-containing precursor and a reducing gas on the metal film formed on the substrate in a process chamber.

Abstract: Embodiments of the present invention provide a process sequence and related hardware for filling a patterned feature on a substrate with a metal, such as copper. The sequence comprises first forming a reliable barrier layer in the patterned feature to prevent diffusion of the metal into the dielectric layer through which the patterned feature is formed. One sequence comprises forming a generally conformal barrier layer over a patterned dielectric, etching the barrier layer at the bottom of the patterned feature, depositing a second barrier layer, and then filling the patterned feature with a metal, such as copper.

Abstract: Embodiments of the invention generally provide a fluid delivery system for an electrochemical plating platform. The fluid delivery system is configured to supply multiple chemistries to multiple plating cells with minimal bubble formation in the fluid delivery system. The system includes a solution mixing system, a fluid distribution manifold in communication with the solution mixing system, a plurality of fluid conduits in fluid communication with the fluid distribution manifold, and a plurality of fluid tanks, each of the plurality of fluid tanks being in fluid communication with at least one of the plurality of fluid conduits.

Abstract: Embodiments of the invention generally provide a method for immersing a substrate into a fluid solution. The method includes loading a substrate into a receiving member configured to support the substrate in a face down orientation, tilting the receiving member to a first tilt angle measured from horizontal, displacing the receiving member toward the fluid solution, and tilting the receiving member to a second tilt angle measured from horizontal during the displacing.

Abstract: A method for forming a tungsten layer on a substrate surface is provided. In one aspect, the method includes positioning the substrate surface in a processing chamber and exposing the substrate surface to a boride. A nucleation layer is then deposited on the substrate surface in the same processing chamber by alternately pulsing a tungsten-containing compound and a reducing gas selected from a group consisting of silane (SiH4), disilane (Si2H6), dichlorosilane (SiCl2H2), derivatives thereof, and combinations thereof. A tungsten bulk fill may then be deposited on the nucleation layer using cyclical deposition, chemical vapor deposition, or physical vapor deposition techniques.

Abstract: Embodiments of the invention generally include a method and intermediate plating solution for plating metal onto a substrate surface. The method generally includes filling the features and/or growing a film layer on the field areas by plating a metal from a first solution on a seed layer under an applied first current, wherein the first solution includes an acid in an amount sufficient to provide a first solution pH of about 6 or less, copper ions, and at least one suppressor. The method may further include substantially filling features by plating metal ions from a second solution onto the substrate under an applied second current to form a metal layer, wherein the second solution includes an acid in an amount sufficient to provide a second solution pH of from about 0.

Abstract: Embodiments of the invention generally provide a substrate processing system and method. The substrate processing system generally includes two primary components. The first component is an interface section having at least one first substrate transfer robot positioned therein, and the second component is at least one processing module in communication with the interface section, the at least one processing module having a pretreatment and post treatment cell, a processing cell, at a second substrate transfer robot positioned therein. The substrate processing method generally includes transporting a dry substrate to a processing module via a dry interface. Once the substrate is positioned in the processing module, a robot transfers the substrate between a treatment cell and a processing cell contained within the processing module to complete a predetermined sequence of processing steps.

Abstract: A valve control system for a semiconductor processing chamber includes a system control computer and a plurality of electrically controlled valves associated with the processing chamber. The system further includes a programmable logic controller in communication with the system control computer and operatively coupled to the electrically controlled valves. The refresh time for control of the valves may be less than 10 milliseconds. Consequently, valve control operations do not significantly extend the period of time required for highly repetitive cycling in atomic layer deposition processes. A hardware interlock may be implemented through the output power supply of the programmable logic controller.

Abstract: Embodiments of the invention provide an electrochemical plating cell. The plating cell includes a fluid basin having an anolyte solution compartment and a catholyte solution compartment, an ionic membrane positioned between the anolyte solution compartment and the catholyte solution compartment, and an anode positioned in the anolyte solution compartment, wherein the ionic membrane comprises a poly tetrafluoroethylene based ionomer.

Abstract: Embodiments of the invention generally provide an electrochemical processing system configured to provide multiple chemistries for a single plating process. The multiple chemistries are generally delivered to individual plating cells positioned on the processing system. The individual chemistries may generally be used to conduct direct plating on a barrier layer, alloy plating, plating on a thin seed layer, optimized feature fill and bulk fill plating, plating with minimized defects, and/or any other plating process wherein multiple chemistries may be utilized to take advantage of the desirable characteristics of each chemistry.

Abstract: A valve control system for a semiconductor processing chamber includes a system control computer and a plurality of electrically controlled valves associated with the processing chamber. The system further includes a programmable logic controller in communication with the system control computer and operatively coupled to the electrically controlled valves. The refresh time for control of the valves may be less than 10 milliseconds. Consequently, valve control operations do not significantly extend the period of time required for highly repetitive cycling in atomic layer deposition processes. A hardware interlock may be implemented through the output power supply of the programmable logic controller.

Abstract: A method for cleaning the electrical contact areas or substrate contact areas of an electrochemical plating contact ring is provided. Embodiments of the method include positioning a substrate on a substrate support member having one or more electrical contacts, chemically plating a metal layer on at least a portion of a surface of the substrate, removing the processed substrate from the support member, and cleaning the one or more electrical contacts with a vapor mixture comprising an alcohol. In another aspect, the method includes spraying the vapor mixture on the electrical contacts while rotating the substrate support member.

Abstract: Embodiments of the invention relate to an apparatus and method of depositing a titanium silicon nitride layer by cyclical deposition. In one aspect, a titanium silicon nitride layer having a variable content or a controlled composition of titanium, silicon, and nitrogen through the depth of the layer may be formed. One embodiment of this variable content titanium silicon nitride layer or tuned titanium silicon nitride layer includes a bottom sub-layer of TiSiX1NY1, a middle sub-layer of TiSiX2NY2, and a top sub-layer of TiSiX3NY3 in which X1 is less than X2 and X3 is less than X2. Another embodiment of a variable content titanium silicon nitride layer includes a bottom sub-layer of TiSiX1NY1 and a top sub-layer of TiSiX2NY2 in which X2 is greater than X1. Still another embodiment of a variable content titanium silicon nitride layer includes a bottom sub-layer of TiSiX1NY1, a middle sub-layer of TiSiX2NY2, and a top sub-layer of TiSiX3NY3 in which X1 is greater than X2 and X3 is greater than X2.

Abstract: Embodiments of the invention are generally directed to a cyclical layer deposition system, which includes a processing chamber; at least one load lock chamber connected to the processing chamber; a plurality of gas injectors connected to the processing chamber. The gas injectors are configured to deliver gas streams into the processing chamber. The system further includes at least one shuttle movable between the at least one load lock chamber and the processing chamber.