The present disclosure describes a method to form a semiconductor device with backside contact structures. The method includes forming a semiconductor device on a first side of a substrate. The semiconductor device includes a source/drain (S/D) region. The method further includes etching a portion of the S/D region on a second side of the substrate to form an opening and forming an epitaxial contact structure on the S/D region in the opening. The second side is opposite to the first side. The epitaxial contact structure includes a first portion in contact with the S/D region in the opening and a second portion on the first portion. A width of the second portion is larger than the first portion.

Stacked integrated circuit devices may include standard cells including a first standard cell in a first row and a second standard cell in a second row immediately adjacent to the first row. Each of the standard cells may include an upper transistor and a lower transistor. The upper transistor may include an upper active region, an upper gate structure, and an upper source/drain region. The lower transistor may include a lower active region, a lower gate structure, and a lower source/drain region. Each of the standard cells may also include a power line and a power via electrically connecting the power line to the lower source/drain region. The power via of the first standard cell and the power via of the second standard cell may be aligned with each other along the first direction.

Embodiments utilize an electro-chemical process to deposit a metal gate electrode in a gate opening in a gate replacement process for a nanosheet FinFET device. Accelerators and suppressors may be used to achieve a bottom-up deposition for a fill material of the metal gate electrode.

A semiconductor device includes a substrate, a first cell having a first functionality, and a second cell having a second functionality. The first cell includes a first portion on a first side of the substrate, wherein the first portion includes a first conductive element; a second portion on a second side of the substrate, wherein the second portion includes a second conductive element; and a first conductive via extending through the substrate and electrically connecting the first conductive element to the second conductive element. The second cell includes a third portion on the first side of the substrate, wherein the third portion includes a third conductive element; a fourth portion on the second side of the substrate, wherein the fourth portion includes a fourth conductive element; and a second conductive via extending through the substrate and electrically connecting the third conductive element to the fourth conductive element.

A semiconductor device with different configurations of contact structures and a method of fabricating the same are disclosed. The method includes forming first and second fin structures on a substrate, forming n- and p-type source/drain (S/D) regions on the first and second fin structures, respectively, forming first and second contact openings on the n- and p-type S/D regions, respectively, forming a carbon-based layer in the first and second contact openings, performing a remote plasma treatment with radicals on the carbon-based layer to form a remote plasma treated layer, selectively removing a portion of the remote plasma treated layer, forming a p-type work function metal (pWFM) silicide layer on the p-type S/D region, and forming an n-type work function metal (nWFM) silicide layer on the pWFM silicide layer and on the n-type S/D region.

A semiconductor device includes a substrate having cell areas and power areas that are alternately arranged in a second direction. Gate structures extend in the second direction. The gate structures are spaced apart from each other in a first direction perpendicular to the second direction. Junction layers are arranged at both sides of each gate structure. The junction layers are arranged in the second direction such that each of the junction layer has a flat portion that is proximate to the power area. Cutting patterns are arranged in the power areas. The cutting patterns extend in the first direction such that each of the gate structures and each of the junction layers in neighboring cell areas are separated from each other by the cutting pattern.

A method of fabricating a semiconductor device includes forming a gate structure, a first edge structure and a second edge structure on a semiconductor strip. The method further includes forming a first source/drain feature between the gate structure and the first edge structure. The method further includes forming a second source/drain feature between the gate structure and the second edge structure, wherein a distance between the gate structure and the first source/drain feature is different from a distance between the gate structure and the second source/drain feature. The method further includes implanting a buried channel in the semiconductor strip, wherein the buried channel is entirely below a top-most surface of the semiconductor strip, a maximum depth of the buried channel is less than a maximum depth of the first source/drain feature, and a dopant concentration of the buried channel is highest under the gate structure.

A semiconductor structure is provided. The semiconductor structure includes: a substrate; discrete channel structures on the substrate in device regions; a power rail line, located in the substrate of a power rail region; a gate structure, extending across the channel structures; source/drain doped regions, located in the channel structures on two sides of the gate structure; an interlayer dielectric layer, located at a side portion of the gate structure; a power rail contact plug, penetrating a partial thickness of the interlayer dielectric layer at a top of the power rail line, the power rail contact plug is in full contact with a top surface of the power rail line in a longitudinal direction; and a source/drain contact layer, located in the interlayer dielectric layer and in contact with the source/drain doped region, on a projection surface parallel to the substrate, the source/drain contact layer extends across the power rail line.

A semiconductor device includes a substrate, an isolation structure, a first gate structure, a second gate structure, a first slot contact structure, a first gate contact structure, and a second gate contact structure. The substrate includes a first active region and a second active region elongated in a first direction respectively. The first gate structure, the second gate structure, and the first slot contact structure are continuously elongated in a second direction respectively. The first gate contact structure and the second gate contact structure are disposed at two opposite sides of the first slot contact structure in the first direction respectively.

A semiconductor device includes a substrate that includes an active pattern, a channel pattern and a source/drain pattern on the active pattern, a gate electrode on the channel pattern, an active contact electrically connected to the source/drain pattern, and a gate contact electrically connected to the gate electrode. The active contact includes a first barrier pattern, a first seed pattern on the first barrier pattern, a first fill pattern on the first seed pattern, and a first metal-containing pattern between the first seed pattern and the first fill pattern. The first metal-containing pattern includes tungsten nitride. A nitrogen concentration of the first metal-containing pattern decreases in a direction toward the substrate.