Abstract: A semiconductor device and method of formation thereof. The semiconductor device includes a portion of a first material that abuts a portion of a second material and surrounds at least a portion of a semiconductor component. The first material has a first composition and a first index of refraction and is of a same type of material as the second material. The second material has a second composition and a second index of refraction. An opening in the first material exposes a portion of the semiconductor component.

Abstract: A low aspect ratio interconnect is provided and includes a metallization layer, a liner and a metallic interconnect. The metallization layer includes bottommost and uppermost surfaces. The uppermost surface has a maximum post-deposition height from the bottommost surface at first metallization layer portions. The metallization layer defines a trench at second metallization layer portions. The liner includes is disposed to line the trench and includes liner sidewalls that have terminal edges that extend to the maximum post-deposition height and lie coplanar with the uppermost surface at the first metallization layer portions. The metallic interconnect is disposed on the liner to fill a trench remainder and has an uppermost interconnect surface that extends to the maximum post-deposition height and lies coplanar with the uppermost surface at the first metallization layer portions.

Abstract: Back end of line metallization structures and processes of fabricating the metallization structures generally include one or more metal filled via structures within a dielectric layer of an interconnect level, wherein at least one of the metal filled via structures includes a bulk metal and a metal alloy overlaying the bulk metal, wherein the bulk metal and metal alloy filled via is coupled to an active circuit.

Abstract: Back end of line metallization structures and processes of fabricating the metallization structures generally include one or more metal filled via structures within a dielectric layer of an interconnect level, wherein at least one of the metal filled via structures includes a bulk metal and a metal alloy overlaying the bulk metal, wherein the bulk metal and metal alloy filled via is coupled to an active circuit.

Abstract: A method for implementing a wet clean process includes cleaning one or more trenches formed in an interlevel dielectric by applying a two-phase cleaning solution. Applying the two-phase cleaning solution includes applying a first component of the two-phase cleaning solution including a diluted acid solution, and reducing capillary force during drying by applying a second component of the two-phase cleaning solution including a chemistry that is less dense than the first component.

Abstract: A method for back end of line (BEOL) integration for one or more interconnects includes forming one or more interconnects by depositing conductive material on a diffusion barrier layer in respective ones of one or more trenches formed within an interlevel dielectric, forming one or more cap layers on respective ones of the one or more interconnects, and selectively etching the diffusion barrier relative to the one or more cap layers to remove portions of the diffusion barrier layer along the interlevel dielectric.

Abstract: Embodiments of the invention are directed to an interconnect stack including a first dielectric layer, a first trench formed in the first dielectric layer, and a first liner deposited in the first trench, wherein the first liner defines a second trench. A first conductive material is in the second trench and deposited over the first dielectric layer and the first conductive material. A third trench extends through the second dielectric layer and is over the first conductive material. A bottom surface of the third trench includes at least a portion of the top surface of the first conductive material. A second liner is in the third trench, on sidewalls of the third trench, and also on the portion of the top surface of the first conductive material. The second liner functions as a cap region configured to counter electro-migration or surface migration of the first conductive material.

Abstract: Embodiments of the invention are directed to an interconnect stack including a first dielectric layer, a first trench formed in the first dielectric layer, and a first liner deposited in the first trench, wherein the first liner defines a second trench. A first conductive material is in the second trench and deposited over the first dielectric layer and the first conductive material. A third trench extends through the second dielectric layer and is over the first conductive material. A bottom surface of the third trench includes at least a portion of the top surface of the first conductive material. A second liner is in the third trench, on sidewalls of the third trench, and also on the portion of the top surface of the first conductive material. The second liner functions as a cap region configured to counter electro-migration or surface migration of the first conductive material.

Abstract: Interconnect structures and processes of fabricating the interconnect structures generally includes a recessed metal conductor and a discontinuous capping layer thereon. The discontinuous “capped” metal interconnect structure provides improved performance and reliability for the semiconductor industry.

Abstract: Back end of line (BEOL) metallization structures and methods according to aspects of the invention generally include forming an interconnect structure including a recessed via structure in an interlayer dielectric. The recessed via structure is lined with a liner layer and filled with a first metal such as copper, tungsten, aluminum, alloys thereof or mixtures thereof. The recessed portion is filled with a second metal such as tantalum, titanium, tungsten, cobalt, ruthenium, iridium, platinum, nitrides thereof, or mixtures thereof, which in combination with the liner layer provides effective barrier properties for the bulk first metal.

Abstract: Techniques are provided to fabricate metallic interconnect structures in a single metallization level, wherein different width metallic interconnect structures are formed of different metallic materials to eliminate or minimize void formation in the metallic interconnect structures. For example, a semiconductor device includes an insulating layer disposed on a substrate, and a first metallic line and a second metallic line formed in the insulating layer. The first metallic line has a first width, and the second metallic line has a second width which is greater than the first width. The first metallic line is formed of a first metallic material, and the second metallic line is formed of a second metallic material, which is different from the first metallic material. For example, the first metallic material is cobalt or ruthenium, and the second metallic material is copper.

Abstract: Back end of line (BEOL) metallization structures and methods according to aspects of the invention generally include forming an interconnect structure including a recessed via structure in an interlayer dielectric. The recessed via structure is lined with a liner layer and filled with a first metal such as copper, tungsten, aluminum, alloys thereof or mixtures thereof. The recessed portion is filled with a second metal such as tantalum, titanium, tungsten, cobalt, ruthenium, iridium, platinum, nitrides thereof, or mixtures thereof, which in combination with the liner layer provides effective barrier properties for the bulk first metal.

Abstract: Interconnect structures and processes of fabricating the interconnect structures generally includes a recessed metal conductor and a discontinuous capping layer thereon. The discontinuous “capped” metal interconnect structure provides improved performance and reliability for the semiconductor industry.

Abstract: A substantially flat bottom electrode for magnetoresistive random access memory (MRAM) devices includes three components: a recessed bulk conductive material such as copper, a conductive liner lining the recess, and a cap layer, wherein the conductive liner is a harder material than the cap layer. The cap layer and the dielectric layer are coplanar having a height differential of less than 3 nanometers. The conductive liner has a lower chemical mechanical planarization removal rate. Also provided are processes for forming the bottom electrode.

Abstract: Techniques are provided to fabricate metallic interconnect structures in a single metallization level, wherein different width metallic interconnect structures are formed of different metallic materials to eliminate or minimize void formation in the metallic interconnect structures. For example, a semiconductor device includes an insulating layer disposed on a substrate, and a first metallic line and a second metallic line formed in the insulating layer. The first metallic line has a first width, and the second metallic line has a second width which is greater than the first width. The first metallic line is formed of a first metallic material, and the second metallic line is formed of a second metallic material, which is different from the first metallic material. For example, the first metallic material is cobalt or ruthenium, and the second metallic material is copper.

Abstract: Semiconductor structures including copper interconnect structures and methods include selective surface modification of copper by providing a CuxTiyNz alloy in the surface. The methods generally include forming a titanium nitride layer on an exposed copper surface followed by annealing to form the CuxTiyNz, alloy in the exposed copper surface. Subsequently, the titanium layer is removed by a selective wet etching.

Abstract: Methods and structures for forming cobalt contact and/or cobalt interconnects includes depositing a stress control layer onto the cobalt layer prior to annealing after which the stress control layer can be removed. The stress control layer prevents formation of defects that can occur in the absence of the stress control layer.

Abstract: Methods for fabricating low-resistivity metallic interconnect structures with self-forming diffusion barrier layers are provided, as well as semiconductor devices comprising low-resistivity metallic interconnect structures with self-formed diffusion barrier layers. For example, a semiconductor device includes a dielectric layer disposed on a substrate, an opening etched in the dielectric layer, a metallic liner layer covering sidewall and bottom surfaces of the opening in the dielectric layer, copper material filling the opening to form an interconnect structure, and a self-formed diffusion barrier layer formed in the sidewall surfaces of the opening of the dielectric layer. The self-formed diffusion barrier layer includes manganese atoms which are diffused into the sidewall surfaces of the dielectric layer.

Abstract: Techniques are provided to fabricate metallic interconnect structures in a single metallization level, wherein different width metallic interconnect structures are formed of different metallic materials to eliminate or minimize void formation in the metallic interconnect structures. For example, a semiconductor device includes an insulating layer disposed on a substrate, and a first metallic line and a second metallic line formed in the insulating layer. The first metallic line has a first width, and the second metallic line has a second width which is greater than the first width. The first metallic line is formed of a first metallic material, and the second metallic line is formed of a second metallic material, which is different from the first metallic material. For example, the first metallic material is cobalt or ruthenium, and the second metallic material is copper.

Abstract: Techniques are provided to fabricate metallic interconnect structures in a single metallization level, wherein different width metallic interconnect structures are formed of different metallic materials to eliminate or minimize void formation in the metallic interconnect structures. For example, a semiconductor device includes an insulating layer disposed on a substrate, and a first metallic line and a second metallic line formed in the insulating layer. The first metallic line has a first width, and the second metallic line has a second width which is greater than the first width. The first metallic line is formed of a first metallic material, and the second metallic line is formed of a second metallic material, which is different from the first metallic material. For example, the first metallic material is cobalt or ruthenium, and the second metallic material is copper.