Patent application number | Description | Published |
20100311236 | COPPER INTERCONNECT STRUCTURE WITH AMORPHOUS TANTALUM IRIDIUM DIFFUSION BARRIER - A method of forming a diffusion barrier for use in semiconductor device manufacturing includes depositing, by a physical vapor deposition (PVD) process, an iridium doped, tantalum based barrier layer over a patterned interlevel dielectric (ILD) layer, wherein the barrier layer is deposited with an iridium concentration of at least 60% by atomic weight such that the barrier layer has a resulting amorphous structure. | 12-09-2010 |
20110017499 | FORMATION OF ALLOY LINER BY REACTION OF DIFFUSION BARRIER AND SEED LAYER FOR INTERCONNECT APPLICATION - An interconnect structure including an alloy liner positioned directly between a diffusion barrier and a Cu alloy seed layer as well as methods for forming such an interconnect structure are provided. The alloy liner of the present invention is formed by thermally reacting a previously deposited diffusion barrier metal alloy layer with an overlying Cu alloy seed layer. During the thermal reaction, the metal alloys from both the diffusion barrier and the Cu alloys seed layer react forming a metal alloy reaction product between the diffusion barrier and the Cu seed layer. | 01-27-2011 |
20110018093 | PROGRAMMABLE ANTI-FUSE STRUCTURE WITH DLC DIELECTRIC LAYER - In one embodiment an anti-fuse structure is provided that includes a first dielectric material having at least a first anti-fuse region and a second anti-fuse region, wherein at least one of the anti-fuse regions includes a conductive region embedded within the first dielectric material. The anti-fuse structure further includes a first diamond like carbon layer having a first conductivity located on at least the first dielectric material in the first anti-fuse region and a second diamond like carbon layer having a second conductivity located on at least the first dielectric material in the second anti-fuse region. In this embodiment, the second conductivity is different from the first conductivity and the first diamond like carbon layer and the second diamond like carbon layer have the same thickness. The anti-fuse structure also includes a second dielectric material located atop the first and second diamond like carbon layers. The second dielectric material includes at least one conductively filled region embedded therein. | 01-27-2011 |
20110062587 | LARGE GRAIN SIZE CONDUCTIVE STRUCTURE FOR NARROW INTERCONNECT OPENINGS - An interconnect structure having reduced electrical resistance and a method of forming such an interconnect structure are provided. The interconnect structure includes a dielectric material including at least one opening therein. The at least one opening is filled with an optional barrier diffusion layer, a grain growth promotion layer, an agglomerated plating seed layer, an optional second plating seed layer a conductive structure. The conductive structure which includes a metal-containing conductive material, typically Cu, has a bamboo microstructure and an average grain size of larger than 0.05 microns. In some embodiments, the conductive structure includes conductive grains that have a (111) crystal orientation. | 03-17-2011 |
20110101538 | CREATION OF VIAS AND TRENCHES WITH DIFFERENT DEPTHS - Embodiments of the invention provide a method of creating vias and trenches with different length. The method includes depositing a plurality of dielectric layers on top of a semiconductor structure with the plurality of dielectric layers being separated by at least one etch-stop layer; creating multiple openings from a top surface of the plurality of dielectric layers down into the plurality of dielectric layers by a non-selective etching process, wherein at least one of the multiple openings has a depth below the etch-step layer; and continuing etching the multiple openings by a selective etching process until one or more openings of the multiple openings that are above the etch-stop layer reach and expose the etch-stop layer. Semiconductor structures made thereby are also provided. | 05-05-2011 |
20110163450 | INTEGRATED CIRCUIT LINE WITH ELECTROMIGRATION BARRIERS - A method for fabricating an integrated circuit comprising an electromigration barrier in a line of the integrated circuit includes forming a spacer; forming a segmented line adjacent to opposing sides of the spacer, the segmented line formed from a first conductive material; removing the spacer to form an empty line break; and filling the empty line break with a second conductive material to form an electromigration barrier that isolates electromigration effects within individual segments of the segmented line. An integrated circuit comprising an electromigration barrier includes a line, the line comprising a first conductive material, the line further comprising a plurality of line segments separated by one or more electromigration barriers, wherein the one or more electromigration barriers comprise a second conductive material that isolates electromigration effects within individual segments of the line. | 07-07-2011 |
20110180309 | INTERCONNECT STRUCTURE EMPLOYING A Mn-GROUP VIIIB ALLOY LINER - A metallic liner stack including at least a Group VIIIB element layer and a CuMn alloy layer is deposited within a trench in a dielectric layer. Copper is deposited on the metallic liner stack and planarized to form a conductive interconnect structure, which can be a metal line, a metal via, or a combination thereof. The deposited copper and the metallic liner stack are annealed before or after planarization. The Mn atoms are gettered by the Group VIIIB element layer to form a metallic alloy liner including Mn and at least one of Group VIIIB elements. Mn within the metallic alloy liner combines with oxygen during the anneal to form MnO, which acts as a strong barrier to oxygen diffusion, thereby enhancing the reliability of the conductive interconnect structure. | 07-28-2011 |
20110272812 | STRUCTURE AND METHOD FOR MANUFACTURING INTERCONNECT STRUCTURES HAVING SELF-ALIGNED DIELECTRIC CAPS - Interconnect structures having self-aligned dielectric caps are provided. At least one metallization level is formed on a substrate. A dielectric cap is selectively deposited on the metallization level. | 11-10-2011 |
20120153503 | CREATION OF VIAS AND TRENCHES WITH DIFFERENT DEPTHS - Embodiments of the invention provide a method of creating vias and trenches with different length. The method includes depositing a plurality of dielectric layers on top of a semiconductor structure with the plurality of dielectric layers being separated by at least one etch-stop layer; creating multiple openings from a top surface of the plurality of dielectric layers down into the plurality of dielectric layers by a non-selective etching process, wherein at least one of the multiple openings has a depth below the etch-step layer; and continuing etching the multiple openings by a selective etching process until one or more openings of the multiple openings that are above the etch-stop layer reach and expose the etch-stop layer. Semiconductor structures made thereby are also provided. | 06-21-2012 |
20120171859 | CREATION OF VIAS AND TRENCHES WITH DIFFERENT DEPTHS - Embodiments of the invention provide a method of creating vias and trenches with different length. The method includes depositing a plurality of dielectric layers on top of a semiconductor structure with the plurality of dielectric layers being separated by at least one etch-stop layer; creating multiple openings from a top surface of the plurality of dielectric layers down into the plurality of dielectric layers by a non-selective etching process, wherein at least one of the multiple openings has a depth below the etch-step layer; and continuing etching the multiple openings by a selective etching process until one or more openings of the multiple openings that are above the etch-stop layer reach and expose the etch-stop layer. Semiconductor structures made thereby are also provided. | 07-05-2012 |
20120175775 | INTEGRATED CIRCUIT LINE WITH ELECTROMIGRATION BARRIERS - An integrated circuit comprising an electromigration barrier includes a line, the line comprising a first conductive material, the line further comprising a plurality of line segments separated by one or more electromigration barriers, wherein the one or more electromigration barriers comprise a second conductive material that isolates electromigration effects within individual segments of the line. | 07-12-2012 |
20130000962 | FORMATION OF ALLOY LINER BY REACTION OF DIFFUSION BARRIER AND SEED LAYER FOR INTERCONNECT APPLICATION - An interconnect structure including an alloy liner positioned directly between a diffusion barrier and a Cu alloy seed layer as well as methods for forming such an interconnect structure are provided. The alloy liner of the present invention is formed by thermally reacting a previously deposited diffusion barrier metal alloy layer with an overlying Cu alloy seed layer. During the thermal reaction, the metal alloys from the both the diffusion barrier and the Cu alloys seed layer react forming a metal alloy reaction product between the diffusion barrier and the Cu seed layer. | 01-03-2013 |
20130178058 | INTERCONNECT STRUCTURE EMPLOYING A Mn-GROUP VIIIB ALLOY LINER - A metallic liner stack including at least a Group VIIIB element layer and a CuMn alloy layer is deposited within a trench in a dielectric layer. Copper is deposited on the metallic liner stack and planarized to form a conductive interconnect structure, which can be a metal line, a metal via, or a combination thereof. The deposited copper and the metallic liner stack are annealed before or after planarization. The Mn atoms are gettered by the Group VIIIB element layer to form a metallic alloy liner including Mn and at least one of Group VIIIB elements. Mn within the metallic alloy liner combines with oxygen during the anneal to form MnO, which acts as a strong barrier to oxygen diffusion, thereby enhancing the reliability of the conductive interconnect structure. | 07-11-2013 |