Abstract: A method is disclosed for depositing a copper seed layer onto a substrate surface. In one embodiment, the method includes providing a substrate having a barrier layer disposed on a substrate surface, wherein the barrier layer has a barrier surface comprising a material selected from the group consisting of cobalt, ruthenium, tungsten, titanium, and a compound of two or more thereof, and exposing the substrate to a non-complexed, acid electrochemical plating solution with a plating bias applied across the substrate surface to deposit a copper-containing seed layer directly on the barrier surface without intervening layer disposed therebetween.

Abstract: The present invention generally relates to apparatus and methods for plating conductive materials on a substrate. One embodiment of the present invention provides an apparatus for plating a conductive material on a substrate. The apparatus comprises a fluid basin configured to retain an electrolyte, a contact ring configured to support the substrate and contact the substrate electrically, and an anode assembly disposed in the fluid basin, wherein the anode assembly comprises a plurality of anode elements arranged in rows.

Abstract: A method and apparatus for adjusting an electric field of an electrochemical processing cell are provided. In one embodiment, a capacitive element is disposed in the processing solution. The strength, shape, or direction of the electric field in the processing solution may be modulated by charging and discharging the capacitive element in a controlled manner. Because the electric field is modulated with out passing a current from the capacitive element to the processing solution, electrochemical reactions do not occur on the interface of the capacitive element and the processing solution, thus, reduces complications caused by unwanted electrochemical reactions.

Abstract: The present invention generally relates to apparatus and methods for plating conductive materials on a substrate. One embodiment of the present invention provides an apparatus for plating a conductive material on a substrate. The apparatus comprises a fluid basin configured to retain an electrolyte, a contact ring configured to support the substrate and contact the substrate electrically, and an anode assembly disposed in the fluid basin, wherein the anode assembly comprises a plurality of anode elements arranged in rows.

Abstract: A method and apparatus for plating a metal onto a substrate. One embodiment of the present invention provides an apparatus for electroplating a substrate. The apparatus comprises a fluid basin, an anode disposed near a bottom of the fluid basin, a restrictor disposed above the anode, and a substrate support member configured to move the substrate within the fluid basin among different elevations relative to the restrictor. Plating profiles on the substrate may be adjusted by changing the elevation of the substrate during plating.

Abstract: A method and apparatus for plating a metal onto a substrate. One embodiment of the present invention provides an apparatus for electroplating a substrate. The apparatus comprises a fluid basin, an anode disposed near a bottom of the fluid basin, a restrictor disposed above the anode, and a substrate support member configured to move the substrate within the fluid basin among different elevations relative to the restrictor. Plating profiles on the substrate may be adjusted by changing the elevation of the substrate during plating.

Abstract: Generally, the process includes depositing a barrier layer on a feature formed in a dielectric layer, decorating the barrier layer with a metal, performing a grafting process, initiating a copper layer and then filing the feature by use of a bulk copper fill process. Copper features formed according to aspects described herein have desirable adhesion properties to a barrier layer formed on a semiconductor substrate and demonstrate enhanced electromigration and stress migration results in the fabricated devices formed on the substrate.

Abstract: A method and apparatus for plating a metal onto a substrate. One embodiment of the invention provides an apparatus for electrochemically plating a substrate. The apparatus comprises a fluid basin configured to retain a plating solution therein, an anode assembly disposed in the fluid basin, a substrate support member configured to support the substrate and contact the substrate electrically, and an encased auxiliary electrode assembly disposed in the fluid basin. The encased auxiliary electrode assembly generally comprises an auxiliary electrode disposed in a protective tube.

Abstract: Generally, the process includes depositing a barrier layer and seed layer on a feature formed in a dielectric layer, performing a grafting process, initiating a copper layer and then filing the feature by use of a bulk copper fill process. Copper features formed according to aspects described herein have desirable adhesion properties to a barrier and seed layers formed on a semiconductor substrate and demonstrate enhanced electromigration and stress migration results in the fabricated devices formed on the substrate.

Abstract: A method and apparatus for adjusting an electric field of an electrochemical processing cell are provided. In one embodiment, a capacitive element is disposed in the processing solution. The strength, shape, or direction of the electric field in the processing solution may be modulated by charging and discharging the capacitive element in a controlled manner. Because the electric field is modulated with out passing a current from the capacitive element to the processing solution, electrochemical reactions do not occur on the interface of the capacitive element and the processing solution, thus, reduces complications caused by unwanted electrochemical reactions.

Abstract: The present invention generally includes deposition and electropolishing methods and an apparatus comprising an electroplating cell and auxiliary cell. In one embodiment for electropolishing a substrate, a cycle is performed in which the substrate is alternately placed in an anolyte solution to remove material and a catholyte solution to deposit material. As the cycle is repeated successively, an exposed layer disposed on the substrate is planarized. In another embodiment, an auxiliary cell may be used to deposit the ultrathin seed layer prior to electroplating.

Abstract: A method and apparatus are provided for plating metal onto a substrate. The method generally includes applying a plating solution comprising at least a leveler to a substrate; substantially filling features in the substrate by plating metal ions from the plating solution onto the substrate, and applying sonic energy to the plating solution across a surface of the substrate prior to completely filling the features.

Abstract: The present invention teaches a method for depositing a copper seed layer onto a substrate surface, generally onto a barrier layer. The barrier layer may include a refractory metal and/or a group 8, 9 or 10 metal. The method includes cathodically pre-treating the substrate in an acid-containing solution. The substrate is then placed into a copper solution (pH?7.0) that includes complexed copper ions and a current or bias is applied across the substrate surface. The complexed copper ions are reduced to deposit a copper seed layer onto the barrier layer. In one aspect, a complex alkaline bath is then used to electrochemically plate a gapfill layer on the substrate surface, followed by overfill in the same bath. In another aspect, an acidic bath ECP gapfill process and overfill process follow the alkaline seed layer process.

Abstract: The present invention generally relates to apparatus and methods for plating conductive materials on a substrate. One embodiment of the present invention provides an apparatus for plating a conductive material on a substrate. The apparatus comprises a fluid basin configured to retain an electrolyte, a contact ring configured to support the substrate and contact the substrate electrically, and an anode assembly disposed in the fluid basin, wherein the anode assembly comprises a plurality of anode elements arranged in rows.

Abstract: Generally, the process includes depositing a barrier layer and seed layer on a feature formed in a dielectric layer, performing a grafting process, initiating a copper layer and then filing the feature by use of a bulk copper fill process. Copper features formed according to aspects described herein have desirable adhesion properties to a barrier and seed layers formed on a semiconductor substrate and demonstrate enhanced electromigration and stress migration results in the fabricated devices formed on the substrate.

Abstract: A method is disclosed for depositing a copper seed layer onto a substrate surface, generally onto a barrier layer that is an alloy of a group VIII metal and a refractory metal. In one aspect, the alloy consists of at least 50% ruthenium and the balance a copper diffusion barrier material. A copper layer is electroplated on the alloy directly. In one aspect, the surface of the barrier layer is conditioned prior to plating to improve adhesion and reduce the critical current density for plating on the barrier layer. The conditioning may include cathodic pre-treatment or a plasma pre-treatment in a hydrogen or hydrogen/helium mixture. In one aspect, the substrate surface is immersed in an acidic plating bath and a nucleation waveform is applied to form a seed layer. In another aspect, the substrate is immersed in a neutral or alkaline copper solution that includes complexed copper ions.

Abstract: Generally, the process includes depositing a barrier layer on a feature formed in a dielectric layer, decorating the barrier layer with a metal, performing a grafting process, initiating a copper layer and then filing the feature by use of a bulk copper fill process. Copper features formed according to aspects described herein have desirable adhesion properties to a barrier layer formed on a semiconductor substrate and demonstrate enhanced electromigration and stress migration results in the fabricated devices formed on the substrate.

Abstract: A method and apparatus for plating a metal onto a substrate. One embodiment of the invention provides an apparatus for electrochemically plating a substrate. The apparatus comprises a fluid basin configured to retain a plating solution therein, an anode assembly disposed in the fluid basin, a substrate support member configured to support the substrate and contact the substrate electrically, and an encased auxiliary electrode assembly disposed in the fluid basin. The encased auxiliary electrode assembly generally comprises an auxiliary electrode disposed in a protective tube.

Abstract: A method and apparatus for plating a metal onto a substrate. One embodiment of the present invention provides an apparatus for electroplating a substrate. The apparatus comprises a fluid basin, an anode disposed near a bottom of the fluid basin, a restrictor disposed above the anode, and a substrate support member configured to move the substrate within the fluid basin among different elevations relative to the restrictor. Plating profiles on the substrate may be adjusted by changing the elevation of the substrate during plating.

Abstract: A method for immersing a substrate into a plating solution. In one embodiment, the method includes applying a first waveform to the substrate as the substrate is being immersed into the plating solution, stopping the application of the first waveform to the substrate as soon as the substrate is fully immersed inside the plating solution, and applying a second waveform to the substrate prior to the substrate being situated into a plating position.