Techniques to form semiconductor device conductive interconnections. In an example, an integrated circuit includes a recessed via and a conductive bridge between a top surface of the recessed via and an adjacent source or drain contact. A transistor device includes a semiconductor material extending from a source or drain region, a gate structure over the semiconductor material, and a contact on the source or drain region. Adjacent to the source or drain region, a deep via structure extends in a vertical direction through an entire thickness of the gate structure. The via structure includes a conductive via that is recessed below a top surface of the conductive contact. A conductive bridge extends between the contact and the conductive via such that the conductive bridge contacts a portion of the contact and at least a portion of a top surface of the conductive via.

An integrated circuit device includes: a rear insulating layer; a nanosheet stacked structure arranged on the rear insulating layer and including a plurality of nanosheets; a pair of source/drain regions positioned on sides of the nanosheet stacked structure in a first horizontal direction; a gate electrode extending in a second horizontal direction intersecting the first horizontal direction, on the nanosheet stacked structure; a contact plug connected to at least one of the pair of source/drain regions; a rear contact plug passing through the rear insulating layer and connected to at least one of the pair of source/drain regions; and a spacer layer including a contact spacer layer surrounding part of a side surface of the rear contact plug.

A semiconductor integrated circuit device includes a plurality of standard cells each having a nanosheet field effect transistor (FET). A first standard cell includes a first buried power rail extending in the X direction and a nanosheet FET having a first nanosheet extending in the X direction. A second standard cell includes a second buried power rail greater in size in the Y direction than the first buried power rail and a nanosheet FET having a second nanosheet greater in size in the Y direction than the first nanosheet.

A semiconductor device includes a backside power delivery network (BSPDN). The semiconductor device includes a substrate, a first active pattern extending in a first direction, on a top surface of the substrate, a second active pattern extending in the first direction, and spaced apart from the first active pattern in a second direction intersecting the first direction, on the top surface of the substrate, a gate structure extending in the second direction, on the first active pattern and the second active pattern, a first source/drain pattern connected to the first active pattern, on a side surface of the gate structure, a second source/drain pattern connected to the second active pattern, on the side surface of the gate structure, back source/drain contacts penetrating the substrate, and a first power line connected to the back source/drain contacts on a bottom surface of the substrate.

An integrated circuit comprising: a plurality of first gate electrodes extending in a second direction perpendicular to a first direction, wherein the plurality of first gate electrodes is in a first row that extends in the first direction; a first active pattern group comprising a plurality of first active patterns that extend in the first row in the first direction and intersecting the plurality of first gate electrodes; a plurality of second gate electrodes extending in the second direction in a second row that extends in the first direction; and a second active pattern group comprising a plurality of second active patterns extending in the second row in the first direction and intersecting the plurality of second gate electrodes, wherein ones of the plurality of first active patterns have different widths in the second direction, and the plurality of second active patterns have a first width in the second direction.

Semiconductor devices and methods of forming the same are provided. Semiconductor devices may include first and second active patterns on a substrate. Each of the first and second active patterns may extend in a first direction. The first and second active patterns may be aligned along the first direction and may be separated by a first trench extending in a second direction. The first trench may define a first sidewall of the first active pattern. The semiconductor devices may also include a channel pattern including first and second semiconductor patterns stacked on the first active pattern, a dummy gate electrode on the channel pattern and extending in the second direction, and a gate spacer on one side of the dummy gate electrode, the one side of the dummy gate electrode being adjacent to the first trench. The gate spacer may cover a first sidewall of the first active pattern.

A semiconductor device includes a substrate that includes a first surface and a second surface, a first source/drain pattern disposed on the first surface of the substrate, a second source/drain pattern disposed on the first surface of the, a first source/drain contact disposed on the first source/drain pattern and connected to the first source/drain pattern, a second source/drain contact disposed on the second source/drain pattern and connected to the second source/drain pattern, a rear wiring line disposed on the second surface of the substrate, a first contact connection via that connects the rear wiring line with the first source/drain contact, a second contact connection via that connects the rear wiring line with the second source/drain contact and is spaced apart from the first contact connection via, and an air gap structure disposed between the first contact connection via and the second contact connection via.

A semiconductor device that includes a lower pattern extending in a first direction, a first channel pattern on the lower pattern, and includes a plurality of first sheet patterns, a second channel pattern on the lower pattern, includes a plurality of second sheet patterns and spaced apart from the first channel pattern, a first gate structure which extends around the first sheet pattern, and includes a first gate electrode and a first gate insulating film, a second gate structure which extends around the second sheet pattern, and includes a second gate electrode and a second gate insulating film, a first gate capping pattern and a second gate capping pattern. The number of first sheet patterns is different from the number of second sheet patterns, and a thickness of the first gate capping pattern is different from a thickness of the second gate capping pattern.

A semiconductor structure according to the present disclosure includes a substrate, a first base fin and a second base fin arising from the substrate, an isolation structure disposed between the first base fin and the second base fin, first channel members disposed over the first base fin, second channel members disposed over the second base fin, a region isolation feature extending into the substrate, a first gate structure wrapping around each of the first channel members, second gate structure wrapping around each of the second channel members, a first gate cut feature extending through the first gate structure and into the isolation feature, and a second gate cut feature extending though the second gate structure and into the isolation feature. Each of the first gate cut feature and the second gate cut feature are spaced apart from the region isolation feature.

A continuous metal on diffusion edge (CMODE) may be used to form a CMODE structure in a semiconductor device after a replacement gate process that is performed to replace the polysilicon dummy gate structures of the semiconductor device with metal gate structures. The CMODE process described herein includes removing a portion of a metal gate structure (as opposed to removing a portion of a polysilicon dummy gate structure) to enable formation of the CMODE structure in a recess left behind by removal of the portion of the metal gate structure.