Embodiments of the present disclosure relate to a method of forming a low-k dielectric material, for example, a low-k gate spacer layer in a FinFET device. The low-k dielectric material may be formed using a precursor having a general chemical structure comprising at least one carbon atom bonded between two silicon atoms. A target k-value of the dielectric material may be achieved by controlling carbon concentration in the dielectric material.

In a method of manufacturing a semiconductor device, a fin structure protruding from a first isolation insulating layer is formed. A second isolation insulating layer made of different material than the first isolation insulating layer is formed so that a first upper portion of the fin structure is exposed. A dummy gate structure is formed over the exposed first upper portion of the first fin structure. The second isolation insulating layer is etched by using the dummy gate structure as an etching mask. The dummy gate structure is removed so that a gate space is formed. The second isolation insulating layer is etched in the gate space so that a second upper portion of the fin structure is exposed from the first isolation insulating layer. A gate dielectric layer and a gate electrode layer are formed over the exposed second portion of the fin structure.

Embodiments of the disclosure are in the field of advanced integrated circuit structure fabrication and, in particular, 10 nanometer node and smaller integrated circuit structure fabrication and the resulting structures. In an example, an integrated circuit structure includes a fin comprising silicon, the fin having a lower fin portion and an upper fin portion. A first insulating layer is directly on sidewalls of the lower fin portion of the fin, wherein the first insulating layer is a non-doped insulating layer comprising silicon and oxygen. A second insulating layer is directly on the first insulating layer directly on the sidewalls of the lower fin portion of the fin, the second insulating layer comprising silicon and nitrogen. A dielectric fill material is directly laterally adjacent to the second insulating layer directly on the first insulating layer directly on the sidewalls of the lower fin portion of the fin.

A semiconductor device including a gate separation region is provided. The semiconductor device includes an isolation region between active regions; interlayer insulating layers on the isolation region; gate line structures overlapping the active regions, disposed on the isolation region, and having end portions facing each other; and a gate separation region disposed on the isolation region, and disposed between the end portions of the gate line structures facing each other and between the interlayer insulating layers. The gate separation region comprises a gap fill layer and a buffer structure, the buffer structure includes a buffer liner disposed between the gap fill layer and the isolation region, between the end portions of the gate line structures facing each other and side surfaces of the gap fill layer, and between the interlayer insulating layers and the side surfaces of the gap fill layer.

Examples of an integrated circuit with a capacitor structure and a method for forming the integrated circuit are provided herein. In some examples, an integrated circuit device includes a substrate and a trench isolation material disposed on the substrate. An isolation structure is disposed on the trench isolation material. A first electrode disposed on the isolation structure, and a second electrode disposed on the isolation structure. A capacitor dielectric is disposed on the isolation structure between the first electrode and the second electrode. In some such examples, the isolation structure includes a first hard mask disposed on the trench isolation material, a dielectric disposed on the first hard mask, and a second hard mask disposed on the dielectric.

The present disclosure provides a semiconductor structure in accordance with some embodiment. The semiconductor structure includes a semiconductor substrate having a first circuit region and a second circuit region; active regions extended from the semiconductor substrate and surrounded by isolation features; first transistors that include first gate stacks formed on the active regions and disposed in the first circuit region, the first gate stacks having a first gate pitch less than a reference pitch; and second transistors that include second gate stacks formed on the active regions and disposed in the second circuit region, the second gate stacks having a second pitch greater than the reference pitch. The second transistors are high-frequency transistors and the first transistors are logic transistors.

An IC structure includes first, second, third, and fourth transistors on a substrate, a first net and a second net. The first net includes a plurality of first metal lines routed on a first metallization layer, and a plurality of first metal vias electrically connecting the plurality of first metal lines to the first and second transistors. The second net includes a plurality of second metal lines routed on a second metallization layer, and a plurality of second metal vias electrically connecting the plurality of second metal lines to the third and fourth transistors. A count of the first metal vias of the first net is less than a count of the second metal vias of the second net, and a line height of the first metal line of the first net is greater than a line height of the second metal line of the second net.

A FinFET that includes a semiconductor substrate that has insulating areas, a fin structure, a gate dielectric layer, a gate electrode structure, a drain structure and a source structure is provided. The fin structure is disposed to extend on the semiconductor substrate between two insulating areas. The gate dielectric layer is disposed to extend across two sides of the fin structure. The gate electrode structure is disposed on the gate dielectric layer. The drain structure is disposed at a first side of the gate electrode structure and has a first resistance relative to the gate electrode. The source structure is disposed at a second side of the gate electrode structure and has a second resistance relative to the gate electrode. The first resistance is larger than the second resistance.

Disclosed systems and methods pertain to finfet based integrated circuits designed with logic cell architectures which support multiple diffusion regions for n-type and p-type diffusions. Different diffusion regions of each logic cell can have different widths or fin counts. Abutting two logic cells is enabled based on like fin counts for corresponding p-diffusion regions and n-diffusion regions of the two logic cells. Diffusion fills are used at common edges between the two logic cells for extending lengths of diffusion, based on the like fin counts. The logic cell architectures support via redundancy and the ability to selectively control threshold voltages of different logic cells with implant tailoring. Half-row height cells can be interleaved with standard full-row height cells.

The semiconductor device includes a first multi-channel active pattern protruding from a substrate, and having a first height, a second multi-channel active pattern on the substrate, being spaced apart from the substrate, and having a second height that is less than the first height, and a gate electrode on the substrate, intersecting the first multi-channel active pattern and the second multi-channel active pattern.