Abstract: Methods of lithographic patterning. A metal hardmask layer is formed on a dielectric layer and a patterned layer is formed on the metal hardmask layer. A metal layer is formed on an area of the metal hardmask layer exposed by an opening in the patterned layer. After the metal layer is formed, the patterned layer is removed from the metal hardmask layer. After the patterned layer is removed, the metal hardmask layer is patterned with the metal layer masking the metal hardmask layer over the area.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to post spacer self-aligned cut structures and methods of manufacture. The method includes: providing a non-mandrel cut; providing a mandrel cut; forming blocking material on underlying conductive material in the non-mandrel cut and the mandrel cut; forming trenches with the blocking material acting as a blocking mask at the mandrel cut and the non-mandrel cut; and filling the trenches with metallization features such that the metallization features have a tip to tip alignment.

Abstract: A device includes an air-gap (i.e., air-gap spacer) formed in situ during the selective, non-conformal deposition of a conductive material. The air-gap is disposed between source/drain contacts and a gate conductor of the device and beneath a portion of the conductive material, and is configured to decrease capacitive coupling between adjacent conductive elements. Prior to deposition of the conductive material, source/drain contact structures are recessed and a selective etch is used to remove sidewall spacers that are disposed between the source/drain contacts and the gate structures.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to skip via structures and methods of manufacture. The structure includes: a first wiring layer with one or more wiring structures; a second wiring layer with one or more wiring structures, located above the first wiring layer; a skip via with metallization, which passes through upper wiring levels including the second wiring layer and which makes contact with the one or more wiring structures of the first wiring layer; and a via structure which comprises a protective material and contacts at least one of the one or more wiring structures at the upper wiring level.

Abstract: Methods of forming self-aligned cuts and structures formed with self-aligned cuts. A dielectric layer is formed on a metal hardmask layer, and a mandrel is formed on the dielectric layer. A cut is formed that extends through the dielectric layer to the metal hardmask layer. A section of a metal layer is formed on an area of the metal hardmask layer exposed by the cut in the dielectric layer. After the metal layer is formed, a spacer is formed on a vertical sidewall of the mandrel.

Abstract: A method includes providing a structure having a dielectric layer, a 1st hardmask layer, a 2nd hardmask layer and a 1st mandrel layer disposed respectively thereon. A 1st mandrel plug is disposed in the 1st mandrel layer. A 2nd mandrel layer is disposed over the 1st mandrel layer. The 1st and 2nd mandrel layers are etched to form a plurality 1st mandrels, wherein the 1st mandrel plug extends entirely through a single 1st mandrel. The 1st mandrel plug is etched such that it is self-aligned with sidewalls of the single 1st mandrel. The 1st mandrels are utilized to form mandrel metal lines in the dielectric layer. The 1st mandrel plug is utilized to form a self-aligned mandrel continuity cut in a single mandrel metal line formed by the single 1st mandrel.

Abstract: A method provides a structure having a FinFET in an Rx region, the FinFET including a channel, source/drain (S/D) regions and a gate, the gate including gate metal. A cap is formed over the gate having a liner and a core. Trench silicide (TS) is disposed on sides of the gate. The TS is recessed to a level above a level of the gate and below a level of the core. The liner is etched to the level of the TS. An oxide layer is disposed over the structure. A CB trench is patterned into the oxide layer within the Rx region to expose the core at a shelf portion of the CB trench. The core is etched to extend the CB trench to a bottom at the gate metal. The shelf portion having a larger area than the bottom. The CB trench is metalized to form a CB contact.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to self aligned interconnect structures and methods of manufacture. The structure includes an interconnect structure which is self-aligned with an upper level via metallization, and both the interconnect structure and the upper level via metallization are composed of a Pt group material.

Abstract: Disclosed are methods of using a lithography-lithography-etch (LLE) technique to form a sidewall spacer pattern for patterning a target layer. In the methods, a photoresist layer is patterned by performing multiple lithographic processes with different photomasks, including a first photomask with a first pattern of parallel bars separated by spaces and a second photomask with a second pattern of opening(s) oriented in an essentially perpendicular direction as compared to the bar(s). The photoresist layer is then developed, creating a third pattern. The third pattern is transferred into a mandrel layer below to form mandrels of different lengths. Then, sidewall spacers are formed on the mandrels and the mandrels are selectively removed to form the sidewall spacer pattern. This sidewall spacer pattern is subsequently used in a sidewall image transfer (SIT) process to pattern a target layer below.

Abstract: Devices and methods of fabricating integrated circuit devices for forming low resistivity interconnects are provided. One method includes, for instance: obtaining an intermediate semiconductor interconnect device having a substrate, a cap layer, and a dielectric matrix including a set of trenches and a set of vias; depositing a barrier layer along a top surface of the semiconductor interconnect device; depositing and annealing a metal interconnect material over a top surface of the barrier layer, wherein the metal interconnect material fills the set of trenches and the set of vias; planarizing a top surface of the intermediate semiconductor interconnect device; exposing a portion of the barrier layer between the set of trenches and the set of vias; and depositing a dielectric cap. Also disclosed is an intermediate device formed by the method.

Abstract: Embodiments of the present disclosure may provide a method of forming an integrated circuit (IC) structure, the method including: providing a structure with: a conductive region, and an inter-level dielectric (ILD) material positioned on the conductive region, wherein the ILD material includes a contact opening to the conductive region; forming a doped metal layer within the contact opening such that the doped metal layer overlies the conductive region, wherein the doped metal layer includes a first metal doped with a second metal; and forming a contact to the conductive region within the contact opening of the ILD material by annealing the doped metal layer such that the second metal diffuses into the ILD material to form an interface liner directly between the annealed doped metal layer and the ILD material.

Abstract: A method provides a structure having a FinFET in an Rx region, the FinFET including a channel, source/drain (S/D) regions and a gate, the gate including gate metal. A cap is formed over the gate having a high-k dielectric liner and a core. Trench silicide (TS) is disposed on sides of the gate. The TS is recessed to a level above a level of the gate and below a level of the cap. An oxide layer is disposed over the structure. A CB trench is patterned into the oxide layer within the Rx region to expose the core and liner at an intermediate portion of the CB trench. The core is selectively etched relative to the liner to extend the CB trench to a bottom at the gate metal. The CB trench is metalized to form a CB contact.

Abstract: A method provides a structure having a FinFET in an Rx region, the FinFET including a channel, source/drain (S/D) regions and a gate, the gate including gate metal. A cap is formed over the gate having a liner and a core. Trench silicide (TS) is disposed on sides of the gate. The TS is recessed to a level above a level of the gate and below a level of the core. The liner is etched to the level of the TS. An oxide layer is disposed over the structure. A CB trench is patterned into the oxide layer within the Rx region to expose the core at a shelf portion of the CB trench. The core is etched to extend the CB trench to a bottom at the gate metal. The shelf portion having a larger area than the bottom. The CB trench is metalized to form a CB contact.

Abstract: Integrated circuit (IC) structure embodiments and methods of forming them with middle of the line (MOL) contacts that incorporate a protective cap, which provides protection from damage during back end of the line (BEOL) processing. Each MOL contact has a main body in a lower portion of a contact opening. The main body has a liner (e.g., a titanium nitride layer) that lines the lower portion and a metal layer on the liner. The MOL contact also has a protective cap in an upper portion of the contact opening above the first metal layer and extending laterally over the liner to the sidewalls of the contact opening. The protective cap has an optional liner, which is different from the liner in the lower portion, and a metal layer, which is either the same or different than the metal in the main body.

Abstract: A method includes providing a structure having a dielectric layer, a 1st hardmask layer, a 2nd hardmask layer and a 1st mandrel layer disposed respectively thereon. A 1st mandrel plug is disposed in the 1st mandrel layer. A 2nd mandrel layer is disposed over the 1st mandrel layer. The 1st and 2nd mandrel layers are etched to form a plurality 1st mandrels, wherein the 1st mandrel plug extends entirely through a single 1st mandrel. The 1st mandrel plug is etched such that it is self-aligned with sidewalls of the single 1st mandrel. The 1st mandrels are utilized to form mandrel metal lines in the dielectric layer. The 1st mandrel plug is utilized to form a self-aligned mandrel continuity cut in a single mandrel metal line formed by the single 1st mandrel.

Abstract: Disclosed are methods of forming integrated circuit (IC) structures with hybrid metallization interconnects. A dual damascene process is performed to form trenches in an upper portion of a dielectric layer and contact holes that extend from the trenches to a gate electrode and to contact plugs on source/drain regions. A first metal is deposited into the contact holes by electroless deposition and a second metal is then deposited. Alternatively, a single damascene process is performed to form a first contact hole through a dielectric layer to a gate electrode and a first metal is deposited therein by electroless deposition. Next, a dual damascene process is performed to form trenches in an upper portion of the dielectric layer, including a trench that traverses the first contact hole, and to form second contact holes that extend from the trenches to contact plugs on source/drain regions. A second metal is then deposited.

Abstract: One illustrative method disclosed includes, among other things, forming a gate contact opening in a layer of insulating material, performing at least one etching process through the gate contact opening to remove a gate cap layer and to expose the gate structure, selectively growing a metal material that is conductively coupled to an upper surface of the gate structure such that the grown metal material contacts all of the sidewalls of the gate contact opening and an air space is formed between a bottom of the grown metal material and a conductive source/drain structure, and forming one or more conductive materials in the gate contact opening above the grown metal material.

Abstract: A method of fabricating raised fin structures is provided, the fabricating including: providing a substrate and at least one dielectric layer over the substrate; forming a trench in the at least one dielectric layer, the trench having a lower portion, a lateral portion, and an upper portion, the upper portion being at least partially laterally offset from the lower portion and being joined to the lower portion by the lateral portion; and, growing a material in the trench to form the raised fin structure, wherein the trench is formed to ensure that any growth defect in the lower portion of the trench terminates either in the lower portion or the lateral portion of the trench and does not extend into the upper portion of the trench.

Abstract: Devices and methods of fabricating integrated circuit devices for forming low resistivity interconnects are provided. One method includes, for instance: obtaining an intermediate semiconductor interconnect device having a substrate, a cap layer, and a dielectric matrix including a set of trenches and a set of vias; depositing a barrier layer along a top surface of the semiconductor interconnect device; depositing and annealing a metal interconnect material over a top surface of the barrier layer, wherein the metal interconnect material fills the set of trenches and the set of vias; planarizing a top surface of the intermediate semiconductor interconnect device; exposing a portion of the barrier layer between the set of trenches and the set of vias; and depositing a dielectric cap. Also disclosed is an intermediate device formed by the method.

Abstract: Devices and methods of fabricating integrated circuit devices for forming low resistivity interconnects with improved adhesion are provided. One method includes, for instance: obtaining an intermediate semiconductor interconnect device having a substrate, a cap layer, and a dielectric matrix including a set of trenches and a set of vias; depositing a metal interconnect material directly over and contacting a top surface of the dielectric matrix, wherein the metal interconnect material fills the set of trenches and the set of vias; depositing a barrier layer over a top surface of the device; annealing the barrier layer to diffuse the barrier layer to a bottom surface of the metal interconnect material; planarizing a top surface of the intermediate semiconductor interconnect device; and depositing a dielectric cap over the intermediate semiconductor interconnect device.