Abstract: A method is presented forming a fully-aligned via (FAV) and airgaps within a semiconductor device. The method includes forming a plurality of copper (Cu) trenches within an insulating layer, forming a plurality of ILD regions over exposed portions of the insulating layer, selectively removing a first section of the ILD regions in an airgap region, and maintaining a second section of the ILD regions in a non-airgap region. The method further includes forming airgaps in the airgap region and forming a via in the non-airgap region contacting a Cu trench of the plurality of Cu trenches.

Abstract: A method is presented for selective deposition on metals using porous low-k materials. The method includes forming alternating layers of a porous dielectric material and a first conductive material, forming a surface aligned monolayer (SAM) over the first conductive material, depositing hydroxamic acid (HA) material over the porous dielectric material, growing an oxide material over the first conductive material, removing the SAM, depositing a dielectric layer adjacent the oxide material, and replacing the oxide material with a second conductive material defining a bottom electrode.

Abstract: A semiconductor structure comprises two or more interconnect lines of a first width in a given interconnect level, and two or more interconnect lines of a second width in the given interconnect level. The two or more interconnect lines of the second width are disposed between a first one of the two or more interconnect lines of the first width and a second one of the two or more interconnect lines of the second width. The two or more interconnect lines of the first width have sidewalls with a negative taper angle. The two or more interconnect lines of the second width have sidewalls with a positive taper angle.

Abstract: A method for fabricating a semiconductor device includes forming one or more layers including at least one of a liner and a barrier along surfaces of a first interlevel dielectric (ILD) layer within a trench, after forming the one or more liners, performing a via etch to form a via opening exposing a first conductive line corresponding to a first metallization level, and forming, within the via opening and on the first conductive line, a barrier-less prefilled via including first conductive material.

Abstract: An interconnect stack structure includes a first metal level of horizontal power line wiring; a second metal level of horizontal power line wiring; wherein the first metal level is not adjacent to the second metal level; two top-via structures comprising a first via and a second via, the two top-via structures being formed above the first metal level; wherein the first via has a first height and the second via has a second height, the first height being different from the second height; wherein the first via extends to connect the first metal level to the second metal level; wherein the second via extends to connect to the first metal level but not the second metal level; damascene intermediate metal lines between the first metal level and the second metal level; and damascene signal lines above the first via and the damascene intermediate metal lines.

Abstract: A semiconductor structure comprising a substrate, a first metal layer on top of the substrate, a second metal layer on top of the first metal layer and a dielectric layer adjacent to the second metal layer and at least part of the first metal layer and on top of at least part of the first metal layer. The first metal layer includes a via. The width of the second metal layer is the same as the width of the via of the first metal layer.

Abstract: A back-end-of-line (BEOL) component includes a substrate and a first layer of dielectric material arranged on the substrate. The first layer of dielectric material includes openings. The BEOL component further includes a first layer of metal material arranged in the openings. The BEOL component further includes an etch stop layer arranged on top of the first layer of dielectric material. The BEOL component further includes a second layer of metal material in direct contact with the first layer of metal material. The second layer of metal material includes at least one projection extending above the etch stop layer. The BEOL component further includes a second layer of dielectric material arranged on top of the etch stop layer and surrounding the at least one projection.

Abstract: A semiconductor structure and a method for managing semiconductor wafer stress are disclosed. The semiconductor structure includes a semiconductor wafer, a first stress layer disposed on and in contact with a backside of the semiconductor wafer, and a second stress layer on and in contact with the first stress layer. The first stress layer exerts a first stress on the semiconductor wafer and the second layer exerts a second stress on the semiconductor wafer that is opposite the first backside stress. The method includes forming a first stress layer on and in contact with a backside of a semiconductor wafer, and further forming a second stress layer on and in contact with the first stress layer. The first stress layer exerts a first stress on the semiconductor wafer and the second stress layer exerts a second stress on the semiconductor wafer that is opposite to the first stress.

Abstract: A semiconductor structure with one or more backside metal layers that include a plurality of portions of a floating metal layer separated by dielectric material from one or more power and ground lines in the backside metal layer. The height of each of the plurality of portions of the floating metal layer in each of the one or more backside metal layers and the distance between adjacent portions of the plurality of portions of the floating metal layer in each of the one or more backside metal layer correlates to the capacitance of each of the one or more backside metal layers.

Abstract: A method for fabricating a semiconductor device including a skip via connection between metallization levels includes subtractively etching first conductive material to form a first via and a skip via on a first conductive line. The first via and the first conductive line are included within a first metallization level. The skip via is used to connect the first metallization level to a third metallization level above a second metallization level. The method further includes forming, on the first via from second conductive material, a second via disposed on a second conductive line. The second via and the second conductive line are included within the second metallization level.

Abstract: Low capacitance and high reliability interconnect structures and methods of manufacture are disclosed. The method includes forming a copper based interconnect structure in an opening of a dielectric material. The method further includes forming a capping layer on the copper based interconnect structure. The method further includes oxidizing the capping layer and any residual material formed on a surface of the dielectric material. The method further includes forming a barrier layer on the capping layer by outdiffusing a material from the copper based interconnect structure to a surface of the capping layer. The method further includes removing the residual material, while the barrier layer on the surface of the capping layer protects the capping layer.

Abstract: Bottom barrier free interconnects are provided. In one aspect, an interconnect structure includes: metal lines embedded in a dielectric; an interlayer dielectric (ILD) disposed over the metal lines; interconnects formed in the ILD on top of the metal lines; a barrier layer separating the interconnects from the ILD, wherein the barrier layer is absent in between the interconnects and the metal lines; and a selective capping layer disposed on the interconnects.

Abstract: Techniques for forming trapezoidal-shaped interconnects are provided. In one aspect, a method for forming an interconnect structure includes: patterning a trench(es) in a dielectric having a V-shaped profile with a rounded bottom; depositing a liner into the trench(es) using PVD which opens-up the trench(es) creating a trapezoidal-shaped profile in the trench(es); removing the liner from the trench(es) selective to the dielectric whereby, following the removing, the trench(es) having the trapezoidal-shaped profile remains in the dielectric; depositing a conformal barrier layer into and lining the trench(es) having the trapezoidal-shaped profile; depositing a conductor into and filling the trench(es) having the trapezoidal-shaped profile over the conformal barrier layer; and polishing the conductor and the conformal barrier layer down to the dielectric. An interconnect structure is also provided.

Abstract: A method of fabricating a semiconductor device includes depositing a spacer material in a trench arranged in a dielectric layer. An end of the trench extends to a metal layer of an interconnect structure. A portion of the spacer material in contact with the metal layer is removed. A recess is formed in the metal layer at the end of the trench.

Abstract: Techniques for forming trapezoidal-shaped interconnects are provided. In one aspect, a method for forming an interconnect structure includes: patterning a trench(es) in a dielectric having a V-shaped profile with a rounded bottom; depositing a liner into the trench(es) using PVD which opens-up the trench(es) creating a trapezoidal-shaped profile in the trench(es); removing the liner from the trench(es) selective to the dielectric whereby, following the removing, the trench(es) having the trapezoidal-shaped profile remains in the dielectric; depositing a conformal barrier layer into and lining the trench(es) having the trapezoidal-shaped profile; depositing a conductor into and filling the trench(es) having the trapezoidal-shaped profile over the conformal barrier layer; and polishing the conductor and the conformal barrier layer down to the dielectric. An interconnect structure is also provided.

Abstract: A method for fabricating a semiconductor device includes forming one or more layers including at least one of a liner and a barrier along surfaces of a first interlevel dielectric (ILD) layer within a trench, after forming the one or more liners, performing a via etch to form a via opening exposing a first conductive line corresponding to a first metallization level, and forming, within the via opening and on the first conductive line, a barrier-less prefilled via including first conductive material.

Abstract: Techniques to enable bottom barrier free interconnects without voids. In one aspect, a method of forming interconnects includes: forming metal lines embedded in a dielectric; depositing a sacrificial dielectric over the metal lines; patterning vias and trenches in the sacrificial dielectric down to the metal lines, with the trenches positioned over the vias; lining the vias and trenches with a barrier layer; depositing a conductor into the vias and trenches over the barrier layer to form the interconnects; forming a selective capping layer on the interconnects; removing the sacrificial dielectric in its entirety; and depositing an interlayer dielectric (ILD) to replace the sacrificial dielectric. An interconnect structure is also provided.

Abstract: A method for fabricating a semiconductor device includes forming one or more layers including at least one of a liner and a barrier along surfaces of a first interlevel dielectric (ILD) layer within a trench, after forming the one or more liners, performing a via etch to form a via opening exposing a first conductive line corresponding to a first metallization level, and forming, within the via opening and on the first conductive line, a barrier-less prefilled via including first conductive material.

Abstract: A technique relates to an integrated circuit. A first dielectric material is formed on a layer, and a second dielectric material is formed on the first dielectric material, the second dielectric material having a different characteristic than the first dielectric material. Conductive material is formed in the first dielectric material, the second dielectric material, and the layer, the conductive material forming interconnects in the layer separated by a stack of the first dielectric material and the second dielectric material. The conductive material forms a self-aligned conductive via on one of the interconnects according to a topography of the stack, the stack of the first dielectric material and the second dielectric material electrically insulating the one of the interconnects from another one of the interconnects.

Abstract: A semiconductor structure and a method for managing semiconductor wafer stress are disclosed. The semiconductor structure includes a semiconductor wafer, a first stress layer disposed on and in contact with a backside of the semiconductor wafer, and a second stress layer on and in contact with the first stress layer. The first stress layer exerts a first stress on the semiconductor wafer and the second layer exerts a second stress on the semiconductor wafer that is opposite the first backside stress. The method includes forming a first stress layer on and in contact with a backside of a semiconductor wafer, and further forming a second stress layer on and in contact with the first stress layer. The first stress layer exerts a first stress on the semiconductor wafer and the second stress layer exerts a second stress on the semiconductor wafer that is opposite to the first stress.