A semiconductor integrated circuit device including standard cells including fin transistors includes, at a cell row end, a cell-row-terminating cell that does not contribute to a logical function of a circuit block. The cell-row-terminating cell includes a plurality of fins extending in an X direction. Ends of the plurality of fins on the inner side of the circuit block are near a gate structure placed at a cell end and do not overlap with the gate structure in a plan view, and ends of the plurality of fins on an outer side of the circuit block overlap with any one of a gate structure in a plan view.

A semiconductor device includes a substrate, a first device region on the substrate, a second device region on the substrate and spaced apart from the first device region in a first direction, a first dummy region between the first device region and the second device region, and an insulating pattern in the first device region, the second device region and the first dummy region, where the first dummy region includes a seed pattern on the insulating pattern, and a seed mask pattern at least partially covering a top surface of the seed pattern and extending from the top surface of the seed pattern along a first sidewall of the seed pattern, where the insulating pattern in the first dummy region is on the substrate, and where the seed pattern includes a transition metal dichalcogenide.

An integrated circuit is provided. In one implementation, the integrated circuit includes a first standard cell, comprising at least one first PMOS transistor disposed in a first row in a semiconductor substrate and at least one first NMOS transistor disposed in a first area of a second row in the semiconductor substrate, and a second standard cell, comprising a plurality of second PMOS transistors disposed in the first row and a third row in the semiconductor substrate and a plurality of second NMOS transistors disposed in a second area of the second row in the semiconductor substrate, wherein the second row is adjacent to the first and third rows and arranged between the first and third rows.

A semiconductor device includes a substrate; a plurality of conductive areas formed on the substrate at a first vertical level; a first wiring layer formed on the substrate at a second vertical level which is higher than the first vertical level, the first wiring layer including first lines that extend in a first direction, one first line of the first lines connected to a first conductive area selected from the plurality of conductive areas through a via contact; a second wiring layer formed on the substrate at a third vertical level which is higher than the second vertical level, the second wiring layer including second lines that extend in a second direction that crosses the first direction, one second line of the second lines connected to a second conductive area selected from the plurality of conductive areas; and a deep via contact spaced apart from lines of the first wiring layer in a horizontal direction and extending from the second conductive area to the one second line.

A semiconductor chip includes four linear-shaped conductive structures that each form a gate electrode of corresponding transistor of a first transistor type and a gate electrode of a corresponding transistor of a second transistor type. First and second ones of the four linear-shaped conductive structures are positioned to have their lengthwise-oriented centerlines separated by a gate electrode pitch. Third and fourth ones of the four linear-shaped conductive structures are also positioned to have their lengthwise-oriented centerlines separated by the gate electrode pitch. The first and third ones of the four linear-shaped conductive structures are positioned to have their lengthwise-oriented centerlines co-aligned and are separated by a first end-to-end spacing. The second and fourth ones of the four linear-shaped conductive structures are positioned to have their lengthwise-oriented centerlines co-aligned and are separated by a second end-to-end spacing substantially equal in size to the first end-to-end spacing.

An integrated circuit structure includes: an integrated circuit structure includes: a first plurality of cell rows extending in a first direction, and a second plurality of cell rows extending in the first direction. Each of the first plurality of cell rows has a first row height and comprises a plurality of first cells disposed therein. Each of the second plurality of cell rows has a second row height different from the first row height and comprises a plurality of second cells disposed therein. The plurality of first cells comprises a first plurality of active regions each of which continuously extends across the plurality of first cells in the first direction. The plurality of second cells comprises a second plurality of active regions each of which continuously extends across the plurality of second cells in the first direction. At least one active region of the first and second pluralities of active regions has a width varying along the first direction.

An integrated circuit includes a standard cell including a first active region extending in a first direction and having a first width, and a filler cell including a second active region of a same type as that of the first active region and being adjacent to the standard cell in the first direction, the second active region extending in the first direction and having a second width which is greater than the first width, wherein the standard cell further includes a first tapering portion of the same type as that of the first active region, the first tapering portion being arranged between the first active region and the second active region.

A semiconductor device includes a substrate; a plurality of conductive areas formed on the substrate at a first vertical level; a first wiring layer formed on the substrate at a second vertical level which is higher than the first vertical level, the first wiring layer including first lines that extend in a first direction, one first line of the first lines connected to a first conductive area selected from the plurality of conductive areas through a via contact; a second wiring layer formed on the substrate at a third vertical level which is higher than the second vertical level, the second wiring layer including second lines that extend in a second direction that crosses the first direction, one second line of the second lines connected to a second conductive area selected from the plurality of conductive areas; and a deep via contact spaced apart from lines of the first wiring layer in a horizontal direction and extending from the second conductive area to the one second line.

A semiconductor chip includes four linear-shaped conductive structures that each form a gate electrode of corresponding transistor of a first transistor type and a gate electrode of a corresponding transistor of a second transistor type. First and second ones of the four linear-shaped conductive structures are positioned to have their lengthwise-oriented centerlines separated by a gate electrode pitch. Third and fourth ones of the four linear-shaped conductive structures are also positioned to have their lengthwise-oriented centerlines separated by the gate electrode pitch. The first and third ones of the four linear-shaped conductive structures are positioned to have their lengthwise-oriented centerlines co-aligned and are separated by a first end-to-end spacing. The second and fourth ones of the four linear-shaped conductive structures are positioned to have their lengthwise-oriented centerlines co-aligned and are separated by a second end-to-end spacing substantially equal in size to the first end-to-end spacing.

An integrated circuit includes a functional cell, and a spare gate cell configured to change or add a function of the functional cell in response to an engineering change order (ECO). The spare gate cell includes transistors configured as a decoupling capacitor before the ECO, and the spare gate cell is configured to change into an ECO cell including an interconnection metal line pattern disposed in the decoupling capacitor after the ECO.