A decoupling integrated circuit including a substrate including first and second active regions extending in a first direction and spaced apart from each other in a second direction intersecting the first direction, a first power rail configured to receive a first power supply and including a first horizontal extension being apart from the first active region in the second direction and extending in the first direction and a first-1 protrusion protruding from the first horizontal extension in a third direction opposite to the second direction, a second power rail configured to receive a second power supply and including a second horizontal extension being apart from the second active region in the second direction and extending in the first direction and a second-1 protrusion protruding from the second horizontal extension in the second direction, the first-1 protrusion and the second-1 protrusion constituting a decoupling capacitor may be provided.

A semiconductor structure includes a power distribution network including a first buried power rail, a power wire, and a first buried via electrically interconnecting the first buried power rail and the power wire. Each of the first buried power rail, the power wire, and the first buried via have a liner on a corresponding bottom surface thereof and sidewalls thereof. The structure also includes a dielectric layer outward of the power distribution network; a first field effect transistor outward of the dielectric layer; a first via trench contact electrically interconnecting a source/drain region of the transistor to the first buried power rail; a first outer wire outward of the first field effect transistor; and an electrical path electrically interconnecting the first outer wire with the power wire.

A lateral diffused metal oxide semiconductor (LDMOS) device includes a first fin-shaped structure on a substrate, a second fin-shaped structure adjacent to the first fin-shaped structure, a shallow trench isolation (STI) between the first fin-shaped structure and the second fin-shaped structure, a first gate structure on the first fin-shaped structure, a second gate structure on the second fin-shaped structure, and an air gap between the first gate structure and the second gate structure.

An integrated circuit device includes: an active region extending in a first horizontal direction on a substrate; a first transistor at a first vertical level on the active region, the first transistor including a first source/drain region having a first conductive type; and a second transistor at a second vertical level that is higher than the first vertical level on the active region, the second transistor including a second source/drain region having a second conductive type and overlapping the first source/drain region in a vertical direction, wherein the first source/drain region and the second source/drain region have different sizes.

An integrated circuit (IC) device including a fin-type active region on a substrate and a gate line on the fin-type active and having a first uppermost surface at a first vertical level, an insulating spacer covering a sidewall of the gate line and having a second uppermost surface at the first vertical level, and an insulating guide film covering the second uppermost surface of the insulating spacer may be provided. The gate line may include a multilayered conductive film structure that includes a plurality of conductive patterns and have a top surface defined by the conductive patterns, which includes at least first and second conductive patterns including different materials from each other and a unified conductive pattern that is in contact with a top surface of each of the conductive patterns and has a top surface that defines the first uppermost surface.

Provided are a semiconductor device and a method for fabricating the same. The semiconductor device includes an active fin protruding upwardly from a substrate and extending in a first direction and a gate structure extending in a second direction intersecting to cross the active fin, where a first width of a lower portion of the gate structure that contacts the active fin is greater than a second width of the lower portion of the gate structure that is spaced apart from the active fin.

An embodiment is a method including forming a raised portion of a substrate, forming fins on the raised portion of the substrate, forming an isolation region surrounding the fins, a first portion of the isolation region being on a top surface of the raised portion of the substrate between adjacent fins, forming a gate structure over the fins, and forming source/drain regions on opposing sides of the gate structure, wherein forming the source/drain regions includes epitaxially growing a first epitaxial layer on the fin adjacent the gate structure, etching back the first epitaxial layer, epitaxially growing a second epitaxial layer on the etched first epitaxial layer, and etching back the second epitaxial layer, the etched second epitaxial layer having a non-faceted top surface, the etched first epitaxial layer and the etched second epitaxial layer forming source/drain regions.

An integrated circuit device includes a metal film and a complex capping layer covering a top surface of the metal film. The metal film includes a first metal, and penetrates at least a portion of an insulating film formed over a substrate. The complex capping layer includes a conductive alloy capping layer covering the top surface of the metal film, and an insulating capping layer covering a top surface of the conductive alloy capping layer and a top surface of the insulating film. The conductive alloy capping layer includes a semiconductor element and a second metal different from the first metal. The insulating capping layer includes a third metal.

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.

Placement methods described in this disclosure provide placement and routing rules where a system implementing the automatic placement and routing (APR) method arranges standard cell structures in a vertical direction that is perpendicular to the fins but parallel to the cell height. Layout methods described in this disclosure also improve device density and further reduce cell height by incorporating vertical power supply lines into standard cell structures. Pin connections can be used to electrically connect the power supply lines to standard cell structures, thus improving device density and performance. The APR process is also configured to rotate standard cells to optimize device layout.