Patent application number | Description | Published |
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 |
20140065815 | BEOL INTEGRATION SCHEME FOR COPPER CMP TO PREVENT DENDRITE FORMATION - Disclosed herein are various methods of forming copper-based conductive structures on integrated circuit devices by performing a copper deposition process to fill the trench or via with copper, which can be performed by fill, plating or electroless deposition. Copper clearing of copper overburden is performed using CMP to stop on an existing liner. Copper in the trenches or vias is recessed by controlled etch. An Nblok cap layer is deposited to cap the trenches or vias so that copper is not exposed to ILD. Nblok overburden and adjacent liner is then removed by CMP. Nblok cap layer is then deposited. The proposed approach is an alternative CMP integration scheme that will eliminate the exposure of copper to ILD during CMP, will prevent any dendrite formation, can be used for all metal layers in BEOL stack, and can be utilized for multiple layers, as necessary, whenever copper CMP is desired. | 03-06-2014 |
20140187036 | INTEGRATION OF Ru WET ETCH AND CMP FOR BEOL INTERCONNECTS WITH Ru LAYER - Embodiments described herein provide approaches for interconnect formation in a semiconductor device. Specifically, a Cu layer is removed to a top surface of an Ru layer using CMP, the Cu layer is removed to form a recess within each of a plurality of trenches of a dielectric of the semiconductor device, and the Ru layer is removed using an etch process (e.g., a wet etch). An additional CMP is performed to reach the desired target trench height and to planarize the wafer. | 07-03-2014 |
20140220775 | METHODS FOR FABRICATING INTEGRATED CIRCUITS HAVING EMBEDDED ELECTRICAL INTERCONNECTS - A method for fabricating integrated circuits includes providing a substrate including a protecting layer over an oxide layer and etching a recess through the protecting layer and into the oxide layer. A barrier material is deposited over the substrate to form a barrier layer including a first region in the recess and a second region outside the recess. A conductive material is deposited over the barrier layer and forms an embedded electrical interconnect in the recess and an overburden region outside the recess. The overburden region of the conductive material is removed and a portion of the embedded electrical interconnect is recessed. Thereafter, the barrier layer is etched to remove the second region of the barrier layer and to recess a portion of the first region of the barrier layer. After etching the barrier layer, the protecting layer is removed from the oxide layer. | 08-07-2014 |
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 |
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 |
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 |