Abstract: A FinFET structure layout includes a semiconductor substrate comprising a plurality of FinFET active areas, and a plurality of fins within each FinFET active area of the plurality of FinFET active areas. The FinFET structure layout further includes a gate having a gate length parallel to the semiconductor substrate and perpendicular to length of the plurality of fins within each FinFET active area of the plurality of FinFET active areas. The FinFET structure layout further includes a plurality of metal features connecting a source region or a drain region of a portion of the plurality of FinFET active areas to a plurality of contacts. The plurality of metal features includes a plurality of metal lines parallel to a FinFET channel direction and a plurality of metal lines parallel to a FinFET channel width direction.

Abstract: A method for generating a layout for a device having FinFETs from a first layout for a device having planar transistors is disclosed. The planar layout is analyzed and corresponding FinFET structures are generated in a matching fashion. The resulting FinFET structures are then optimized. Dummy patterns and a new metal layer may be generated before the FinFET layout is verified and outputted.

Abstract: The present disclosure provides an integrated circuit structure. The integrated circuit structure includes a substrate having an IC device formed therein; a first dielectric material layer disposed on the substrate and having a first trench formed therein; and a first composite interconnect feature disposed in the first trench and electrically coupled with the IC device. The first composite interconnect feature includes a first barrier layer disposed on sidewalls of the first trench; a first metal layer disposed on the first barrier layer; and a first graphene layer disposed on the metal layer.

Abstract: A method and system is provided for efficiently varying the composition of the metal interconnects for a semiconductor device. A metal interconnect according to the present disclosure has an intermediate layer on a dielectric material, the intermediate layer having a relatively higher concentration of an impurity metal along with a primary metal, the impurity metal having a lower reduction potential than the primary metal. The metal interconnect has a main layer of the metal alloy interconnect on top of the intermediate layer and surrounded by the intermediate layer, the main layer having a relatively higher concentration of the primary metal than the intermediate layer, wherein the intermediate and main layers of the metal alloy interconnect each maintains a material uniformity.

Abstract: A semiconductor device comprises a substrate comprising a major surface; a p-type Field Effect Transistor (pFET) comprising: a P-gate stack over the major surface, a P-strained region in the substrate adjacent to one side of the P-gate stack, wherein a lattice constant of the P-strained region is different from a lattice constant of the substrate, wherein the P-strained region has a first top surface higher than the major surface; and a P-silicide region on the P-strained region; and an n-type Field Effect Transistor (nFET) comprising: an N-gate stack over the major surface, an N-strained region in the substrate adjacent to one side of the N-gate stack, wherein a lattice constant of the N-strained region is different from a lattice constant of the substrate, wherein the N-strained region has a second top surface lower than the major surface and a N-silicide region on the N-strained region.

Abstract: The present disclosure provides an integrated circuit structure. The integrated circuit structure includes a substrate having an IC device formed therein; a first dielectric material layer disposed on the substrate and having a first trench formed therein; and a first composite interconnect feature disposed in the first trench and electrically coupled with the IC device. The first composite interconnect feature includes a first barrier layer disposed on sidewalls of the first trench; a first metal layer disposed on the first barrier layer; and a first graphene layer disposed on the metal layer.

Abstract: A semiconductor device comprises a substrate comprising a major surface; a p-type Field Effect Transistor (pFET) comprising: a P-gate stack over the major surface, a P-strained region in the substrate adjacent to one side of the P-gate stack, wherein a lattice constant of the P-strained region is different from a lattice constant of the substrate, wherein the P-strained region has a first top surface higher than the major surface; and a P-silicide region on the P-strained region; and an n-type Field Effect Transistor (nFET) comprising: an N-gate stack over the major surface, an N-strained region in the substrate adjacent to one side of the N-gate stack, wherein a lattice constant of the N-strained region is different from a lattice constant of the substrate, wherein the N-strained region has a second top surface lower than the major surface and a N-silicide region on the N-strained region.

Abstract: The present disclosure provides an integrated circuit structure. The integrated circuit structure includes a substrate having an IC device formed therein; a first dielectric material layer disposed on the substrate and having a first trench formed therein; and a first composite interconnect feature disposed in the first trench and electrically coupled with the IC device. The first composite interconnect feature includes a first barrier layer disposed on sidewalls of the first trench; a first metal layer disposed on the first barrier layer; and a first graphene layer disposed on the metal layer.

Abstract: A method for generating a layout for a device having FinFETs from a first layout for a device having planar transistors is disclosed. The planar layout is analyzed and corresponding FinFET structures are generated in a matching fashion. The resulting FinFET structures are then optimized. Dummy patterns and a new metal layer may be generated before the FinFET layout is verified and outputted.

Abstract: A method and system is provided for efficiently varying the composition of the metal interconnects for a semiconductor device. A metal interconnect according to the present disclosure has an intermediate layer on a dielectric material, the intermediate layer having a relatively higher concentration of an impurity metal along with a primary metal, the impurity metal having a lower reduction potential than the primary metal. The metal interconnect has a main layer of the metal alloy interconnect on top of the intermediate layer and surrounded by the intermediate layer, the main layer having a relatively higher concentration of the primary metal than the intermediate layer, wherein the intermediate and main layers of the metal alloy interconnect each maintains a material uniformity.

Abstract: A method for fabricating a semiconductor device is disclosed. First, a semiconductor substrate having a doped region(s) is provided. Thereafter, a pre-amorphous implantation process and neutral (or non-neutral) species implantation process is performed over the doped region(s) of the semiconductor substrate. Subsequently, a silicide is formed in the doped region(s). By conducting a pre-amorphous implantation combined with a neutral species implantation, the present invention reduces the contact resistance, such as at the contact area silicide and source/drain substrate interface.

Abstract: A method and system is provided for efficiently varying the composition of the metal interconnects for a semiconductor device. A metal interconnect according to the present disclosure has an intermediate layer on a dielectric material, the intermediate layer having a relatively higher concentration of an impurity metal along with a primary metal, the impurity metal having a lower reduction potential than the primary metal. The metal interconnect has a main layer of the metal alloy interconnect on top of the intermediate layer and surrounded by the intermediate layer, the main layer having a relatively higher concentration of the primary metal than the intermediate layer, wherein the intermediate and main layers of the metal alloy interconnect each maintains a material uniformity.

Abstract: A chemical solution for an electro chemical plating process includes an electro chemical plating solution; and an additive, added in the electro chemical plating solution, substantially consisting of a polymer with one or more kinds of impurities, wherein each kind of the impurities has a density, with respect to the polymer, lower then 1019 atoms/cc.

Abstract: A method for fabricating a semiconductor device is disclosed. First, a semiconductor substrate having a doped region(s) is provided. Thereafter, a pre-amorphous implantation process and neutral (or non-neutral) species implantation process is performed over the doped region(s) of the semiconductor substrate. Subsequently, a silicide is formed in the doped region(s). By conducting a pre-amorphous implantation combined with a neutral species implantation, the present invention reduces the contact resistance, such as at the contact area silicide and source/drain substrate interface.

Abstract: A selective electroless plating operation provides for the selective deposition of a metal film only on exposed silicon surfaces of a semiconductor substrate and not on other surfaces such as dielectric surfaces. The plating solution includes metal ions and advantageously also includes dopant impurity ions. The pure metal or metal alloy film formed on the exposed silicon surfaces is then heat treated to form a metal silicide on the exposed silicon surfaces and to drive the dopant impurities to the interface formed between the exposed silicon surfaces and the metal silicide film.

Abstract: Methods for fabricating interconnect structures are provided. An exemplary method for fabricating an interconnect comprises providing a substrate with a first dielectric layer thereon. At least one conductive feature is formed in the first dielectric layer. A conductive cap is selectively formed to overlie the conductive feature. A surface treatment is performed on the first dielectric layer and the conductive cap. A second dielectric layer is then formed to overlie the first dielectric layer.

Abstract: A method of forming an integrated circuit interconnect structure is presented. A first conductive line is formed over a semiconductor substrate. A conductive cap layer is formed on the first conductive line to improve device reliability. An etch stop layer (ESL) is formed on the conductive cap layer. An inter-level dielectric (IMD) is formed on the ESL. A via opening and a trench are formed in the ESL, IMD, and conductive cap layer. A recess is formed in the first conductive line. The recess can be formed by over etching when the first dielectric is etched, or by a separate process such as argon sputtering. A second conductive line is formed filling the trench, opening and recess.

Abstract: A method of electrochemical deposition (ECD) provides a barrier and a seed layer on a substrate. The surfaces of the substrate are pre-treated before a metal layer is electrochemically deposited thereon in an electrochemical plating cell with a physical or a chemical surface treatment process. The electrochemical plating cell is covered by a cap to prevent evaporation of the electrolyte solution. The electrochemical plating cell includes a substrate holder assembly with a lift seal, e.g., with a contact angle ? less than 90° between the lift seal and the substrate. The substrate holder assembly includes a substrate chuck at the rear side of the substrate.

Abstract: A method of electrochemical deposition (ECD) provides a barrier and a seed layer on a substrate. The surfaces of the substrate are pre-treated before a metal layer is electrochemically deposited thereon in an electrochemical plating cell with a physical or a chemical surface treatment process. The electrochemical plating cell is covered by a cap to prevent evaporation of the electrolyte solution. The electrochemical plating cell includes a substrate holder assembly with a lift seal, e.g., with a contact angle ? less than 90° between the lift seal and the substrate. The substrate holder assembly includes a substrate chuck at the rear side of the substrate.

Abstract: A method and system is provided for efficiently varying the composition of the metal interconnects for a semiconductor device. A metal interconnect according to the present disclosure has an intermediate layer on a dielectric material, the intermediate layer having a relatively higher concentration of an impurity metal along with a primary metal, the impurity metal having a lower reduction potential than the primary metal. The metal interconnect has a main layer of the metal alloy interconnect on top of the intermediate layer and surrounded by the intermediate layer, the main layer having a relatively higher concentration of the primary metal than the intermediate layer, wherein the intermediate and main layers of the metal alloy interconnect each maintains a material uniformity.