Abstract: A method for forming an interconnect structure, the interconnect structure comprising: a lower level wire having a side and a bottom, the lower level wire comprising: a lower core conductor and a lower conductive liner, the lower conductive liner on the side and the bottom of the lower level wire; an upper level wire having a side and a bottom, the upper level wire comprising an upper core conductor and an upper conductive liner, the upper conductive liner on the side and the bottom of the upper level wire; and the upper conductive liner in contact with the lower core conductor and also in contact with the lower conductive liner in a liner-to-liner contact region.

Abstract: Device and method of fabricating device. The device includes a dual damascene line having a metal line and a via, and a redundant liner arranged to divide the metal line. The method includes forming a trench in a metal stripe of a dual damascene line, depositing a barrier layer in the trench, and filling a remainder of the trench with metal.

Abstract: An interconnect structure, comprising: a lower level wire having a side and a bottom, the lower level wire comprising: a lower core conductor and a lower conductive liner, the lower conductive liner on the side and the bottom of the lower level wire; an upper level wire having a side and a bottom, the upper level wire comprising an upper core conductor and an upper conductive liner, the upper conductive liner on the side and the bottom of the upper level wire; and the upper conductive liner in contact with the lower core conductor and also in contact with the lower conductive liner in a liner-to-liner contact region.

Abstract: An edge seal around the periphery of an integrated circuit device which environmentally protects the copper circuitry from cracks that may form in the low-k interlevel dielectric during dicing. The edge seal essentially constitutes a dielectric wall between the copper circuitry and the low-k interlevel dielectric near the periphery of the integrated circuit device. The dielectric wall is of a different material than the low-k interlevel dielectric.

Abstract: The present invention provides an interconnect structure that includes a diffusion barrier which is positioned within the structure in a fashion that increases the reliability and lifetime of the interconnect structure.

Abstract: A multilevel semiconductor integrated circuit (IC) structure including a first interconnect level including a layer of dielectric material over a semiconductor substrate, the layer of dielectric material comprising a dense material for passivating semiconductor devices and local interconnects underneath; multiple interconnect layers of dielectric material formed above the layer of dense dielectric material, each layer of dielectric material including at least a layer of low-k dielectric material; and, a set of stacked via-studs in the low-k dielectric material layers, each of said set of stacked via studs interconnecting one or more patterned conductive structures, a conductive structure including a cantilever formed in the low-k dielectric material.

Abstract: An interconnect structure for a semiconductor device includes a metallization line formed within a low-k dielectric material, the metallization line being surrounded on bottom and side surfaces thereof by a liner material. An embedded dielectric cap is formed over a top surface of the metallization line, wherein the embedded dielectric cap has a sufficient thickness so as to separate a top surface of the liner material from a hardmask layer formed over the low-k dielectric material.

Abstract: An interconnect structure for a semiconductor device includes a metallization line formed within a low-k dielectric material, the metallization line being surrounded on bottom and side surfaces thereof by a liner material. An embedded dielectric cap is formed over a top surface of the metallization line, wherein the embedded dielectric cap has a sufficient thickness so as to separate a top surface of the liner material from a hardmask layer formed over the low-k dielectric material.

Abstract: A multilevel semiconductor integrated circuit (IC) structure including a first interconnect level including a layer of dielectric material over a semiconductor substrate, the layer of dielectric material comprising a dense material for passivating semiconductor devices and local interconnects underneath; multiple interconnect layers of dielectric material formed above the layer of dense dielectric material, each layer of dielectric material including at least a layer of low-k dielectric material; and, a set of stacked via-studs in the low-k dielectric material layers, each of said set of stacked via studs interconnecting one or more patterned conductive structures, a conductive structure including a cantilever formed in the low-k dielectric material.

Abstract: An edge seal around the periphery of an integrated circuit device which environmentally protects the copper circuitry from cracks that may form in the low-k interlevel dielectric during dicing. The edge seal essentially constitutes a dielectric wall between the copper circuitry and the low-k interlevel dielectric near the periphery of the integrated circuit device. The dielectric wall is of a different material than the low-k interlevel dielectric.

Abstract: An edge seal around the periphery of an integrated circuit device which environmentally protects the copper circuitry from cracks that may form in the low-k interlevel dielectric during dicing. The edge seal essentially constitutes a dielectric wall between the copper circuitry and the low-k interlevel dielectric near the periphery of the integrated circuit device. The dielectric wall is of a different material than the low-k interlevel dielectric.

Abstract: An edge seal around the periphery of an integrated circuit device which environmentally protects the copper circuitry from cracks that may form in the low-k interlevel dielectric during dicing. The edge seal essentially constitutes a dielectric wall between the copper circuitry and the low-k interlevel dielectric near the periphery of the integrated circuit device. The dielectric wall is of a different material than the low-k interlevel dielectric.

Abstract: An advanced back-end-of-line (BEOL) metallization structure is disclosed. The structure includes a diffusion barrier or cap layer having a low dielectric constant (low-k). The cap layer is formed of amorphous nitrogenated hydrogenated silicon cabride, and has a dielectric constant (k) of less than about 5. A method for forming the BEOL metallization structure is also disclosed, where the cap layer is deposited using a plasma-enhanced chemical vapor deposition (PE CVD) process. The invention is particularly useful in interconnect structure comprising low-k dielectric material for the inter-layer dielectric (ILD) and copper for the conductors.

Abstract: An interconnect structure, comprising: a lower level wire having a side and a bottom, the lower level wire comprising: a lower core conductor and a lower conductive liner, the lower conductive liner on the side and the bottom of the lower level wire; an upper level wire having a side and a bottom, the upper level wire comprising an upper core conductor and an upper conductive liner, the upper conductive liner on the side and the bottom of the upper level wire; and the upper conductive liner in contact with the lower core conductor and also in contact with the lower conductive liner in a liner-to-liner contact region.

Abstract: A wire interconnect structure for electrically and mechanically connecting an integrated circuit chip to a substrate and a process for manufacturing the same. The wire interconnect structure comprises an insulator layer disposed on an integrated circuit chip and an electrically conductive post extending through the insulator layer to the integrated circuit chip. The post has an elongated body, a bottom at one end of the body which is mechanically and electrically connected to the integrated circuit chip, and a top having a spherical shape at the opposite end of the body which extends outward from the insulator layer.

Abstract: A method is provided for the fabrication of fuses within a semiconductor IC structure, which fuses are delectable by a laser pulse or a low voltage electrical pulse typically below 3.5 V to reroute the electrical circuitry of the structure to remove a faulty element. The fuses are formed on the surface of circuitry which is coplanar with a surrounding dielectric such as the circuitry formed by a Damascene method. A preferred fuse material is silicon-chrome-oxygen and the preferred circuitry is copper.

Abstract: A two-step masking process is disclosed for forming a ball limiting metallurgy (BLM) pad structure for a solder joint interconnection used between a support substrate and a semiconductor chip. A solder non-wettable layer and a solder wettable layer are deposited on the surface of a support substrate or semiconductor chip which are to be connected. A phased transition layer is deposited between the wettable and non-wettable layers. A thin photo-resist mask defines an area of the solder wettable and phased layers which are etched to form a raised, wettable frustum cone portion. A second mask is deposited on the surface of the support substrate or semiconductor chip, and has an opening concentrically positioned about the frustum cone. Solder is deposited in the opening and covers the frustum cone and the area about its periphery. When solidified, the solder, acting as a mask, is used to sub-etch the underlying solder non-wettable layer thereby defining the BLM pad.

Abstract: Etching processes are disclosed for producing a graded or stepped edge profile in a contact pad formed between a chip passivating layer and a solder bump. The stepped edge profile reduces edge stress that tends to cause cracking in the underlying passivating layer. The pad comprises a bottom layer of chromium, a top layer of copper and an intermediate layer of phased chromium-copper. An intermetallic layer of CuSn forms if and when the solder is reflowed, in accordance with certain disclosed variations of the process. In all the variations, the solder is used as an etching mask in combination with several different etching techniques including electroetching, wet etching, anisotropic dry etching and ion beam etching.

Abstract: The present invention relates generally to a new interconnection and a method for making the same, and more particularly, to an elongated solder interconnection and a method for making the same. On an electronic carrier, a pad is formed on which a solder mass is deposited and capped with a metal layer, thereby forming an elongated solder interconnection. A further elongated solder interconnection can now be formed by forming a second solder mass on the first solder mass that has been capped by a metal layer. Additional elongated solder interconnection can be formed by capping the preceding solder mass and/or the last solder mass with a metal capping layer. Alternatively, the encapsulating layer can be in the form of a sidewall spacer formed on the sidewalls of the solder mass.

Abstract: The present invention relates generally to a new interconnection and a method for making the same, and more particularly, to an elongated solder interconnection and a method for making the same. On an electronic carrier, a pad is formed on which a solder mass is deposited and capped with a metal layer, thereby forming an elongated solder interconnection. A further elongated solder interconnection can now be formed by forming a second solder mass on the first solder mass that has been capped by a metal layer. Additional elongated solder interconnection can be formed by capping the preceding solder mass and/or the last solder mass with a metal capping layer. Alternatively, the encapsulating layer can be in the form of a sidewall spacer formed on the sidewalls of the solder mass.