Patent application number | Description | Published |
20130244421 | METHODS OF FORMING COPPER-BASED CONDUCTIVE STRUCTURES ON AN INTEGRATED CIRCUIT DEVICE - Disclosed herein are various methods of forming copper-based conductive structures on integrated circuit devices. In one example, the method includes the steps of forming a trench/via in a layer of insulating material, forming a copper-based seed layer above the layer of insulating material and in the trench/via, performing a heating process on the copper-based seed layer to increase an amount of the copper-based seed layer positioned proximate a bottom of the trench/via, performing an etching process on said copper-based seed layer and performing an electroless copper deposition process to fill the trench/via with a copper-based material. | 09-19-2013 |
20130244422 | METHODS OF FORMING COPPER-BASED CONDUCTIVE STRUCTURES ON SEMICONDUCTOR DEVICES - Disclosed herein are various methods of forming copper-based conductive structures on semiconductor devices, such as transistors. In one example, the method involves performing a first etching process through a patterned metal hard mask layer to define an opening in a layer of insulating material, performing a second etching process through the opening in the layer of insulating material that exposes a portion of an underlying copper-containing structure, performing a wet etching process to remove the patterned metal hard mask layer, performing a selective metal deposition process through the opening in the layer of insulating material to selectively form a metal region on the copper-containing structure and, after forming the metal region, forming a copper-containing structure in the opening above the metal region. | 09-19-2013 |
20130309863 | METHODS OF FORMING COPPER-BASED CONDUCTIVE STRUCTURES BY FORMING A COPPER-BASED SEED LAYER HAVING AN AS-DEPOSITED THICKNESS PROFILE AND THEREAFTER PERFORMING AN ETCHING PROCESS AND ELECTROLESS COPPER DEPOSITION - Disclosed herein are various methods of forming copper-based conductive structures on integrated circuit devices. In one example, the method includes forming a trench/via in a layer of insulating material, performing a deposition process to form an as-deposited copper-based seed layer above the layer of insulating material in the trench/via, wherein the copper-based seed layer has a first portion that is positioned above a bottom of the trench/via that is thicker than second portions of the copper seed layer that are positioned above sidewalls of the trench/via, performing an etching process on the as-deposited copper-based seed layer to substantially remove portions of the second portions of the as-deposited copper-based seed layer and performing an electroless deposition process to fill the trench/via with a copper-based material. | 11-21-2013 |
20130309868 | METHODS FOR FORMING AN INTEGRATED CIRCUIT WITH STRAIGHTENED RECESS PROFILE - Methods are provided for forming an integrated circuit. In an embodiment, the method includes forming a sacrificial mandrel overlying a base substrate. Sidewall spacers are formed adjacent sidewalls of the sacrificial mandrel. The sidewall spacers have a lower portion that is proximal to the base substrate, and the lower portion has a substantially perpendicular outer surface relative to the base substrate. The sidewall spacers also have an upper portion that is spaced from the base substrate. The upper portion has a sloped outer surface. A first dielectric layer is formed overlying the base substrate and is conformal to at least a portion of the upper portion of the sidewall spacers. The upper portion of the sidewall spacers is removed after forming the first dielectric layer to form a recess having a re-entrant profile in the first dielectric layer. The re-entrant profile of the recess is straightened. | 11-21-2013 |
20130334532 | STRESS GAUGE COMPRISED OF A PIEZOELECTRIC MATERIAL FOR USE WITH INTEGRATED CIRCUIT PRODUCTS - In one example, a stress gauge for an integrated circuit product is disclosed that includes a layer of insulating material, a body positioned at least partially in the layer of insulating material, wherein the body is comprised of a material having a piezoelectric constant of at least about 0.1 pm/V, and a plurality of spaced apart conductive contacts, each of which is conductively coupled to the body. | 12-19-2013 |
20140021613 | MULTI-LAYER BARRIER LAYER FOR INTERCONNECT STRUCTURE - A method for forming an interconnect structure includes forming a recess in a dielectric layer of a substrate. An adhesion barrier layer is formed to line the recess. A first stress level is present across a first interface between the adhesion barrier layer and the dielectric layer. A stress-reducing barrier layer is formed over the adhesion barrier layer. The stress-reducing barrier layer reduces the first stress level to provide a second stress level, less than the first stress level, across a second interface between the adhesion barrier layer, the stress-reducing barrier layer, and the dielectric layer. The recess is filled with a fill layer. | 01-23-2014 |
20140021615 | MULTI-LAYER BARRIER LAYER STACKS FOR INTERCONNECT STRUCTURES - The present disclosure is generally directed to multi-layer barrier layer stacks for interconnect structures that may be used to reduce mechanical stress levels between the interconnect structure and a dielectric material layer in which the interconnect structure is formed. One illustrative method disclosed herein includes forming a recess in a dielectric layer of a substrate and forming an adhesion barrier layer including an alloy of tantalum and at least one transition metal other than tantalum to line the recess, wherein forming the adhesion barrier layer includes creating a first stress level across a first interface between the adhesion barrier layer and the dielectric layer. The method also includes forming a stress-reducing barrier layer including tantalum over the adhesion barrier layer, wherein the stress-reducing barrier layer reduces the first stress level to a second stress level less than the first stress level, and filling the recess with a fill layer. | 01-23-2014 |
20140024212 | MULTI-LAYER BARRIER LAYER FOR INTERCONNECT STRUCTURE - A method for forming an interconnect structure includes forming a recess in a dielectric layer of a substrate. An adhesion barrier layer is formed to line the recess. A first stress level is present across a first interface between the adhesion barrier layer and the dielectric layer. A stress-reducing barrier layer is formed over the adhesion barrier layer. The stress-reducing barrier layer reduces the first stress level to provide a second stress level, less than the first stress level, across a second interface between the adhesion barrier layer, the stress-reducing barrier layer, and the dielectric layer. The recess is filled with a fill layer. | 01-23-2014 |
20140027910 | METHOD FOR REDUCING WETTABILITY OF INTERCONNECT MATERIAL AT CORNER INTERFACE AND DEVICE INCORPORATING SAME - A method for forming an interconnect structure includes forming a recess in a dielectric layer of a substrate, forming a first transition metal layer in the recess on corner portions of the recess, and forming a second transition metal layer in the recess over the first transition metal layer to line the recess. The method further includes filling the recess with a fill layer and annealing the substrate so that the first transition metal layer and the second transition metal layer form an alloy portion proximate the corner portions during the annealing, the alloy portion having a reduced wettability for a material of the fill layer than the second transition metal. Additionally, the method includes polishing the substrate to remove portions of the fill layer extending above the recess. | 01-30-2014 |
20140057435 | METHODS OF FORMING A METAL CAP LAYER ON COPPER-BASED CONDUCTIVE STRUCTURES ON AN INTEGRATED CIRCUIT DEVICE - Disclosed herein are various methods of forming a metal cap layer on copper-based conductive structures on integrated circuit devices, and integrated circuit devices having such a structure. In one example, the method includes the steps of forming a conductive feature comprised of copper in a layer of insulating material, performing a metal removal process to remove a portion of the conductive feature and thereby define a recess above a residual portion of the copper feature, and performing a selective deposition process to form a cap layer comprised of cobalt, manganese, CoWP or NiWP within the recess. | 02-27-2014 |
20140097538 | SEMICONDUCTOR DEVICE HAVING A SELF-FORMING BARRIER LAYER AT VIA BOTTOM - An approach for forming a semiconductor device is provided. In general, the device is formed by providing a metal layer, a cap layer over the metal layer, and an ultra low k layer over the cap layer. A via is then formed through the ultra low k layer and the cap layer. Once the via is formed, a barrier layer (e.g., cobalt (Co), tantalum (Ta), cobalt-tungsten-phosphide (CoWP), or other metal capable of acting as a copper (CU) diffusion barrier) is selectively applied to a bottom surface of the via. A liner layer (e.g., manganese (MN) or aluminum (AL)) is then applied to a set of sidewalls of the via. The via may then be filled with a subsequent metal layer (with or without a seed layer), and the device may the then be further processed (e.g., annealed). | 04-10-2014 |
20140110798 | METHODS OF FORMING A SEMICONDUCTOR DEVICE WITH LOW-K SPACERS AND THE RESULTING DEVICE - One method disclosed herein includes forming at least one sacrificial sidewall spacer adjacent a sacrificial gate structure that is formed above a semiconducting substrate, removing at least a portion of the sacrificial gate structure to thereby define a gate cavity that is laterally defined by the sacrificial spacer, forming a replacement gate structure in the gate cavity, removing the sacrificial spacer to thereby define a spacer cavity adjacent the replacement gate structure, and forming a low-k spacer in the spacer cavity. A novel device disclosed herein includes a gate structure positioned above a semiconducting substrate, wherein the gate insulation layer has two upstanding portions that are substantially vertically oriented relative to an upper surface of the substrate. The device further includes a low-k sidewall spacer positioned adjacent each of the vertically oriented upstanding portions of the gate insulation layer. | 04-24-2014 |
20140138779 | INTEGRATED CIRCUITS AND METHODS FOR FABRICATING INTEGRATED CIRCUITS WITH REDUCED PARASITIC CAPACITANCE - Integrated circuits and methods for fabricating integrated circuits are provided. In an embodiment, a method for fabricating an integrated circuit includes forming a sacrificial gate structure over a semiconductor substrate. A spacer is formed around the sacrificial gate structure and a dielectric material is deposited over the spacer and semiconductor substrate. The method includes selectively etching the spacer to form a trench between the sacrificial gate structure and the dielectric material. The trench is bounded by a trench surface upon which a replacement spacer material is deposited. The method merges an upper region of the replacement spacer material to enclose a void within the replacement spacer material. | 05-22-2014 |
20140145332 | METHODS OF FORMING GRAPHENE LINERS AND/OR CAP LAYERS ON COPPER-BASED CONDUCTIVE STRUCTURES - One illustrative method disclosed herein includes forming a trench/via in a layer of insulating material, forming a graphene liner layer in at least the trench/via, forming a copper-based seed layer on the graphene liner layer, depositing a bulk copper-based material on the copper-based seed layer so as to overfill the trench/via, and performing at least one chemical mechanical polishing process to remove at least excess amounts of the bulk copper-based material and the copper-based seed layer positioned outside of the trench/via to thereby define a copper-based conductive structure with a graphene liner layer positioned between the copper-based conductive structure and the layer of insulating material. | 05-29-2014 |
20140210088 | METHOD FOR REDUCING WETTABILITY OF INTERCONNECT MATERIAL AT CORNER INTERFACE AND DEVICE INCORPORATING SAME - A semiconductor device includes a recess defined in a dielectric layer, the recess having an upper sidewall portion extending to an upper corner of the recess and a lower sidewall portion below the upper sidewall portion. An interconnect structure is positioned in the recess. The interconnect structure includes a continuous liner layer having upper and lower layer portions positioned laterally adjacent to the upper and lower sidewall portions, respectively. The upper layer portion includes an alloy of a first transition metal and a second transition metal and the lower layer portion includes the second transition metal but not the first transition metal. The interconnect structure also includes a fill material substantially filling the recess, wherein the second transition metal has a higher wettability for the fill material than the alloy. | 07-31-2014 |
20140217588 | METHODS OF FORMING COPPER-BASED NITRIDE LINER/PASSIVATION LAYERS FOR CONDUCTIVE COPPER STRUCTURES AND THE RESULTING DEVICE - One illustrative method disclosed herein includes forming a trench/via in a layer of insulating material, forming a barrier layer in the trench/via, forming a copper-based seed layer on the barrier layer, converting at least a portion of the copper-based seed layer into a copper-based nitride layer, depositing a bulk copper-based material on the copper-based nitride layer so as to overfill the trench/via and performing at least one chemical mechanical polishing process to remove excess materials positioned outside of the trench/via to thereby define a copper-based conductive structure. A device disclosed herein includes a layer of insulating material, a copper-based conductive structure positioned in a trench/via within the layer of insulating material and a copper-based silicon or germanium nitride layer positioned between the copper-based conductive structure and the layer of insulating material. | 08-07-2014 |
20140217591 | MULTI-LAYER BARRIER LAYER FOR INTERCONNECT STRUCTURE - A semiconductor device includes a dielectric layer positioned above a substrate of the semiconductor device and a recess defined in the dielectric layer. An adhesion barrier layer is positioned on and in direct contact with at least the sidewalls of the recess, a barrier layer interface being defined where the adhesion barrier layer directly contacts the dielectric layer. A stress-reducing barrier layer is positioned adjacent to the adhesion barrier layer, wherein the stress-reducing barrier layer is adapted to reduce a stress level across the barrier layer interface from a first stress level to a second stress level that is less than the first stress level. At least one layer of a conductive fill material is positioned over the stress-reducing barrier layer, the at least one layer of the conductive fill material substantially filling the recess. | 08-07-2014 |
20140246775 | METHODS OF FORMING NON-CONTINUOUS CONDUCTIVE LAYERS FOR CONDUCTIVE STRUCTURES ON AN INTEGRATED CIRCUIT PRODUCT - One illustrative method disclosed herein includes forming a trench/via in a layer of insulating material, forming a non-continuous layer comprised of a plurality of spaced-apart conductive structures on the layer of insulating material in the trench/via, wherein portions of the layer of insulating material not covered by the plurality of spaced-apart conductive structures remain exposed, forming at least one barrier layer on the non-continuous layer, wherein the barrier layer contacts the spaced-apart conductive structures and the exposed portions of the layer of insulating material, forming at least one liner layer above the barrier layer, and forming a conductive structure in the trench/via above the liner layer. | 09-04-2014 |
20140252616 | ELECTROLESS FILL OF TRENCH IN SEMICONDUCTOR STRUCTURE - A trench in an inter-layer dielectric formed on a semiconductor substrate is defined by a bottom and sidewalls. A copper barrier lines the trench with a copper-growth-promoting liner over the barrier. The trench has bulk copper filling it, and includes voids in the copper. The copper with voids is removed, including from the sidewalls, leaving a void-free copper portion at the bottom. Immersion in an electroless copper bath promotes upward growth of copper on top of the void-free copper portion without inward sidewall copper growth, resulting in a void-free copper fill of the trench. | 09-11-2014 |
20140252617 | BARRIER LAYER CONFORMALITY IN COPPER INTERCONNECTS - A process of modulating the thickness of a barrier layer deposited on the sidewalls and floor of a recessed feature in a semiconductor substrate is disclosed. The process includes altering the surface of the conductive feature on which the barrier layer is deposited by annealing in a reducing atmosphere and optionally additionally, silylating the dielectric surface that forms the sidewalls of the recessed feature. | 09-11-2014 |
20140264876 | MULTI-LAYER BARRIER LAYER STACKS FOR INTERCONNECT STRUCTURES - A semiconductor device includes a recess defined in a dielectric layer and an interconnect structure defined in the recess. The interconnect structure includes a first barrier layer lining the recess, the first barrier layer including an alloy of tantalum and a first transition metal other than tantalum, wherein a first interface between the first barrier layer and the dielectric layer has a first stress level. A second barrier layer is positioned on the first barrier layer, the second barrier layer including at least one of tantalum and tantalum nitride, wherein a second interface between the second barrier layer and the first barrier layer has a second stress level that is less than the first stress level. The interconnect structure further includes a fill material substantially filling the recess. | 09-18-2014 |
20140291847 | METHODS OF FORMING A BARRIER SYSTEM CONTAINING AN ALLOY OF METALS INTRODUCED INTO THE BARRIER SYSTEM, AND AN INTEGRATED CIRCUIT PRODUCT CONTAINING SUCH A BARRIER SYSTEM - One illustrative method disclosed herein includes forming a trench/via in a layer of insulating material, forming a barrier system comprised of at least one barrier material and at least two metallic elements, and performing a heating process to form a metal alloy comprised of the at least two metallic elements in the barrier system. Also disclosed is a device that comprises a trench/via in a layer of insulating material, a barrier system positioned in the trench/via, wherein the barrier system comprises at least one barrier material and a metal alloy comprised of at least two metallic elements that are comprised of materials other than the at least one barrier material, and a conductive structure positioned in the trench/via above the barrier system. | 10-02-2014 |
20140327140 | INTEGRATED CIRCUITS AND METHODS FOR FABRICATING INTEGRATED CIRCUITS WITH IMPROVED CONTACT STRUCTURES - Integrated circuits and methods for fabricating integrated circuits are provided. In an exemplary embodiment, a method for fabricating integrated circuits includes providing a semiconductor substrate disposed with a device therein and/or thereon. A contact structure including a barrier layer and a plug metal overlying the barrier layer is formed in electrical contact with the device. A hardmask is formed overlying the contact structure. The method includes performing an etch to form a via opening through the hardmask and to expose the barrier layer and the plug metal. Further, the method removes a remaining portion of the hardmask with a wet etchant, while the contact structure is configured to inhibit the wet etchant from etching the barrier layer. In the method, the via opening is filled with a conductive material to form an interconnect to the contact structure. | 11-06-2014 |
20140353802 | METHODS FOR INTEGRATION OF PORE STUFFING MATERIAL - A process is provided for methods of reducing damage to an ultra-low k layer during fabrication. In one aspect, a method includes: providing a cured ultra-low k film containing pores filled with a pore-stuffing material; and modifying an exposed surface of the ultra-low k film to provide a modified layer in the ultra-low k film. In another aspect, a semiconductor device comprising a modified layer on a surface of an ultra-low k film is provided. | 12-04-2014 |
20140353805 | METHODS OF SEMICONDUCTOR CONTAMINANT REMOVAL USING SUPERCRITICAL FLUID - A process is provided for the removal of contaminants from a semiconductor device, for example, removing contaminants from pores of an ultra-low k film. In one aspect, a method includes: providing a dielectric layer with contaminant-containing pores and exposing the dielectric layer to a supercritical fluid. The supercritical fluid can dissolve and remove the contaminants. In another aspect, an intermediate semiconductor device structure is provided that contains a dielectric layer with contaminant-containing pores and a supercritical fluid within the pores. In another aspect, a semiconductor device structure with a dielectric layer containing uncontaminated pores is provided. | 12-04-2014 |
20140353835 | METHODS OF SELF-FORMING BARRIER INTEGRATION WITH PORE STUFFED ULK MATERIAL - A process is provided for methods of reducing contamination of the self-forming barrier of an ultra-low k layer during semiconductor fabrication. In one aspect, a method includes: providing a cured ultra-low k film which contains at least one trench, and the pores of the film are filled with a pore-stuffing material; removing exposed pore-stuffing material at the surface of the trench to form exposed pores; and forming a self-forming barrier layer on the surface of the trench. | 12-04-2014 |
20140357078 | METHODS OF FORMING CONDUCTIVE STRUCTURES USING A SACRIFICIAL MATERIAL DURING AN ETCHING PROCESS THAT IS PERFORMED TO REMOVE A METAL HARD MASK - One illustrative method disclosed herein includes forming at least one layer of insulating material above a conductive structure, forming a patterned hard mask comprised of metal above the layer of insulating material, performing at least one etching process to define a cavity in the layer of insulating material that exposes at least a portion of a conductive structure, forming a layer of sacrificial material that covers the exposed portion of the conductive structure, with the layer of sacrificial material in position, performing at least one second etching process to remove the patterned hard mask while leaving the layer of sacrificial material in position within the cavity, and removing the layer of sacrificial material positioned within the cavity. | 12-04-2014 |
20140357079 | METHODS OF FORMING CONDUCTIVE STRUCTURES USING A SACRIFICIAL MATERIAL DURING A METAL HARD MASK REMOVAL PROCESS - One illustrative method disclosed herein includes forming at least one layer of insulating material above a conductive structure, forming a patterned hard mask comprised of metal above the layer of insulating material, performing at least one etching process to define a cavity in the layer of insulating material, forming a layer of sacrificial material so as to overfill the cavity, performing at least one planarization process to remove a portion of the layer of sacrificial material and the patterned hard mask while leaving a remaining portion of the layer of sacrificial material within the cavity, and removing the remaining portion of the layer of sacrificial material positioned within the cavity. | 12-04-2014 |
20140361435 | METHODS OF FORMING COPPER-BASED NITRIDE LINER/PASSIVATION LAYERS FOR CONDUCTIVE COPPER STRUCTURES AND THE RESULTING DEVICE - One illustrative method disclosed herein includes forming a trench/via in a layer of insulating material, forming a barrier layer in the trench/via, forming a copper-based seed layer on the barrier layer, converting at least a portion of the copper-based seed layer into a copper-based nitride layer, depositing a bulk copper-based material on the copper-based nitride layer so as to overfill the trench/via and performing at least one chemical mechanical polishing process to remove excess materials positioned outside of the trench/via to thereby define a copper-based conductive structure. A device disclosed herein includes a layer of insulating material, a copper-based conductive structure positioned in a trench/via within the layer of insulating material and a copper-based silicon or germanium nitride layer positioned between the copper-based conductive structure and the layer of insulating material. | 12-11-2014 |
20150064903 | METHODS FOR FABRICATING INTEGRATED CIRCUITS USING CHEMICAL MECHANICAL PLANARIZATION TO RECESS METAL - Methods for fabricating integrated circuits using chemical mechanical planarization (CMP) for recessing metal are provided. In an embodiment, a method for fabricating an integrated circuit includes filling a trench with a metal and forming an overburden portion of the metal outside of the trench. The method further includes performing a planarization process with an etching slurry to remove the overburden portion of the metal and to recess the metal within the trench. | 03-05-2015 |