In an embodiment, a semiconductor device may include a plurality of first nanostructures. The plurality of first nanostructures extend between first source/drain regions. The semiconductor device may also include a plurality of second nanostructures over the plurality of first nanostructures. The plurality of second nanostructures extend between second source/drain regions. The device may furthermore include a first gate stack around the plurality of first nanostructures. The device may in addition include a second gate stack over the first gate stack and disposed around the plurality of second nanostructures. The device may moreover include a vertical interconnect structure extending through the first and second gate stacks. The device may also include a frontside contact electrically coupled to a frontside of the vertical interconnect structure and a backside contact electrically coupled to a backside of the vertical interconnect structure.

A semiconductor device structure is described. The structure includes a fin structure formed on a substrate, a source/drain feature disposed adjacent the fin structure and over the substrate, wherein a top surface of the source/drain feature and a front side of the substrate are substantially co-planar, an isolation trench extending from the front side of the substrate towards a backside of the substrate, and a backside via contact extending from the backside of the substrate towards and in contact with the source/drain feature, wherein the backside via contact and the isolation trench are parallelly arranged and separated from each other by a constant gap along boundaries of the backside via contact and the isolation trench.

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.

An integrated circuit includes a transistor including a plurality of stacked channels. A first dielectric wall structure is positioned on a first lateral side of the stacked channels. A second dielectric wall structure is positioned on a second lateral side of the stacked channels. A dielectric home structure is positioned above the top channel. A gate electrode includes a vertical column extending vertically between the second dielectric wall structure and the stacked channels. The gate electrode includes finger portions extending laterally from the vertical column between the stacked channels.

A semiconductor device includes a semiconductor substrate, a first semiconductor structure, a second semiconductor structure, a third semiconductor structure, a dielectric wall, and a first isolation feature. The first semiconductor structure, the second semiconductor structure and the third semiconductor structure are disposed on the semiconductor substrate. The first semiconductor structure is disposed between the second semiconductor structure and the third semiconductor structure. The dielectric wall is disposed on the semiconductor substrate and is connected between the first semiconductor structure and the second semiconductor structure. The first isolation feature is disposed between the first semiconductor structure and the third semiconductor structure, and extends into the semiconductor substrate.

The present disclosure describes a semiconductor device having a contact structure isolated from a source/drain structure. The semiconductor structure includes a gate structure on a substrate, first and second source/drain (S/D) structures on opposite sides of the gate structure, an isolation layer on the second S/D structure, a third S/D structure adjacent to and separate from the second S/D structure, and a S/D contact structure on the isolation layer and the third S/D structure. The isolation layer separates the S/D contact structure from the second S/D structure.

The integrated circuit (IC) structure includes a semiconductor substrate, a first active region, a dummy fill region, a second active region, first metal gate structures, and second metal gate structures. The first active region is on the semiconductor substrate. The dummy fill region is on the semiconductor substrate. The second active region is on the semiconductor substrate and spaced apart from the first active region by the dummy fill region. The first metal gate structures extend in the first active region and have a first gate pitch and a first gate width. The second metal gate structures extend in the second active region and have a second gate width greater than the first gate width and a second gate pitch being an integer times the first gate pitch, and the integer being two or more.

Provided is a semiconductor device including a substrate, a lower power line disposed under the substrate, a source/drain pattern on the substrate, a channel pattern, on side surfaces of the source/drain pattern, including a plurality of semiconductor patterns stacked on each other, a gate electrode between the plurality of semiconductor patterns, a backside active contact penetrating the substrate to electrically connect the lower power line and the source/drain pattern, and a backside isolation structure penetrating the substrate and the backside active contact, and disposed under the gate electrode. An uppermost surface of the backside active contact is located at a higher level than an uppermost surface of the backside isolation structure.

A method of forming a semiconductor device includes: forming a gate structure over a fin; forming an interlayer dielectric (ILD) layer over the fin around the gate structure; forming a first dielectric plug and a second dielectric plug in the gate structure on opposing sides of the fin, where the first and second dielectric plugs cut the gate structure into a plurality of discrete segments; forming a patterned mask layer over the ILD layer, where an opening of the patterned mask layer exposes a segment of the gate structure interposed between the first and second dielectric plugs; etching, using the patterned mask layer as an etching mask, the segment of the gate structure using an isotropic etching process to form a recess in the gate structure; extending the recess into the fin by performing an anisotropic etching process; and after extending the recess, filling the recess with a dielectric material.

A method of fabricating a semiconductor device includes providing a partially-fabricated semiconductor device including a dummy gate structure disposed over a semiconductor layer stack. In some embodiments, the method further includes removing the dummy gate structure and at least a portion of each semiconductor layer of the semiconductor layer stack to form a trench. In some examples, the method further includes forming one or more refill layers in a bottom portion of the trench and forming one or more refill layers in a top portion of the trench over the bottom portion of the trench. In some embodiments, the one or more refill layers in the top and bottom portions of the trench respectively define top and bottom portions of an isolation structure. In some examples, at least one refill layer of respective ones of the top and bottom portions of the isolation structure have a different material composition.