Semiconductor device and the manufacturing method thereof are disclosed herein. An exemplary semiconductor device comprises a substrate, at least two gate structures disposed over the substrate, each of the at least two gate structures including a gate electrode and a spacer disposed along sidewalls of the gate electrode, wherein the spacer includes a refill portion and a bottom portion, the refill portion of the spacer has a funnel shape such that a top surface of the refill portion of the spacer is larger than a bottom surface of the refill portion of the spacer, and a source/drain contact disposed over the substrate and between the spacers of the at least two gate structures.

The present disclosure describes a fin field-effect transistor (FinFET) standard cell with double self-aligned contacts. The FinFET standard cell with double self-aligned contacts includes a self-aligned gate contact spanning over a diffusion bonding hole and a self-aligned diffusion bonding hole contact spanning over a gate, and the FinFET device further includes a cap layer between the two self-aligned contacts so as to separate the two self-aligned contacts, thereby further reducing the size of the active fin or a dummy fin so as to further reduce the area of the FinFET standard cell, to prevent a bridge connection between adjacent M0 structures like the M0A and M0P, thereby improving yield of manufacturing.

A multi-stack semiconductor device includes: a lower-stack transistor structure including a lower active region and a lower gate structure, the lower active region including a lower channel structure, and the lower gate structure surrounding the lower channel structure; an upper-stack transistor structure vertically stacked above the lower-stack transistor structure, and including an upper active region and an upper gate structure, the upper active region including an upper channel structure, and the upper gate structure surrounding the upper channel structure; and at least one gate contact plug contacting a top surface of the lower gate structure, wherein the lower gate structure and the upper gate structure have a substantially same size in a plan view, and wherein the lower gate structure is not entirely overlapped by the upper gate structure in a vertical direction.

Semiconductor structures and methods for manufacturing the same are provided. The semiconductor structure includes a substrate and first nanostructures and second nanostructures formed over the substrate. The semiconductor structure also includes a gate structure including a first portion wrapping around the first nanostructures and a second portion wrapping around the second nanostructures. The semiconductor structure also includes a dielectric feature sandwiched between the first portion and the second portion of the gate structure. In addition, the dielectric feature includes a bottom portion and a top portion over the bottom portion, and the top portion of the dielectric feature includes a shell layer and a core portion surrounded by the shell layer.

A method for forming a stacked transistor includes forming a sacrificial cap over a first interconnect of a lower level transistor. The method further includes forming an upper level transistor above the sacrificial cap. The method further includes removing the sacrificial cap to form an opening such that the opening is delimited by the upper level transistor. The method further includes forming a second interconnect in the opening such that the second interconnect is in direct contact with the first interconnect.

A method of forming a semiconductor device can comprise providing a first shift region in which to determine a first displacement. A second shift region may be provided in which to determine a second displacement. A unique electrically conductive structure may be formed comprising traces to account for the first displacement and the second displacement. The electrically conductive structure may comprise traces comprising a first portion within the first shift region and a second portion of traces in the second shift region laterally offset from the first portion of traces. A third portion of the traces may be provided in the routing area between the first shift region and the second shift region. A unique variable metal fill may be formed within the fill area. The variable metal fill may be electrically isolated from the unique electrically conductive structure.

A semiconductor device includes: an active pattern extending in a first direction on a substrate; a first lower source/drain pattern and a second lower source/drain pattern provided on the active pattern and spaced apart from each other in the first direction; a first upper source/drain pattern provided on the first lower source/drain pattern; a second upper source/drain pattern provided on the second lower source/drain pattern; and a gate electrode crossing the active pattern and extending in a second direction intersecting the first direction. The gate electrode includes an overlapping portion overlapping the active pattern in a third direction perpendicular to the first direction and the second direction. A length of the overlapping portion in the second direction is less than a length of the first lower source/drain pattern in the second direction.

A semiconductor device includes active regions extending in a first direction on a substrate; a gate electrode intersecting the active regions on the substrate, extending in a second direction, and including a contact region protruding upwardly; and an interconnection line on the gate electrode and connected to the contact region, wherein the contact region includes a lower region having a first width in the second direction and an upper region located on the lower region and having a second width smaller than the first width in the second direction, and wherein at least one side surface of the contact region in the second direction has a point at which an inclination or a curvature is changed between the lower region and the upper region.

An integrated circuit includes a substrate, an interconnection part, and an isolating region located between the substrate and the interconnection part. A decoy structure is located within the isolating region and includes a silicided sector which is electrically isolated from the substrate.

A semiconductor device structure is provided. The semiconductor device structure includes a gate stack and a source/drain contact structure formed over a substrate. A first gate spacer is separated the gate stack from the source/drain contact structure and extends above top surfaces of the gate stack and the source/drain contact structure. An insulating capping layer covers the top surface of the gate stack and extends on the top surface of the first gate spacer. A conductive via structure partially covers the top surface of the insulating capping layer and the top surface of the source/drain contact structure. A first insulating layer surrounds the conductive via structure and partially covers the top surface of the source/drain contact structure.