An integrated circuit includes a set of transistors including a set of active regions, a set of power rails, a first set of conductors and a first conductor. The set of active regions extends in a first direction, and is on a first level. The set of power rails extends in the first direction and is on a second level. The set of power rails has a first width. The first set of conductors extends in the first direction, is on the second level, and overlaps the set of active regions. The first set of conductors has a second width. The first conductor extends in the first direction, is on the second level and is between the first set of conductors. The first conductor has the first width, electrically couples a first transistor of the set of transistors to a second transistor of the set of transistors.

An integrated circuit includes a first-voltage power rail and a second-voltage power rail in a first connection layer, and includes a first-voltage underlayer power rail and a second-voltage underlayer power rail below the first connection layer. Each of the first-voltage and second-voltage power rails extends in a second direction that is perpendicular to a first direction. Each of the first-voltage and second-voltage underlayer power rails extends in the first direction. The integrated circuit includes a first via-connector connecting the first-voltage power rail with the first-voltage underlayer power rail, and a second via-connector connecting the second-voltage power rail with the second-voltage underlayer power rail.

An integrated circuit is disclosure. The integrated circuit includes a first pair of power rails, a set of conductive lines arranged in the first layer parallel to the first pair of power rails, a first set of active areas. The integrated circuit further includes a first gate arranged along the second direction, between the first pair of power rails, and crossing the first set of active areas in a layout view, wherein the first gate is configured to be shared by a first transistor of a first type and a second transistor of a second type; and a second gate and a third gate, in which the second gate is configured to be a control terminal of a third transistor, and the third gate is configured to be a control terminal of a fourth transistor which is coupled to the control terminal of the third transistor.

An integrated circuit device includes a device layer having devices spaced in accordance with a predetermined device pitch, a first metal interconnection layer disposed above the device layer and coupled to the device layer, and a second metal interconnection layer disposed above the first metal interconnection layer and coupled to the first metal interconnection layer through a first via layer. The second metal interconnection layer has metal lines spaced in accordance with a predetermined metal line pitch, and a ratio of the predetermined metal line pitch to predetermined device pitch is less than 1.

An integrated circuit includes plural standard cells performing a same function. The standard cells include a first standard cell and a second standard cell, and the first standard cell and the second standard cell are to the same as each other in terms of an arrangement of internal conductive patterns and are different from each other in terms of a position of a via formed over a gate line through which an input signal is input.

Semiconductor structures are provided. Each transistor includes a first source/drain region over a semiconductor fin, a second source/drain region over the semiconductor fin, a channel region in the semiconductor fin and between the first and second source/drain regions, and a metal gate electrode formed on the channel region and extending in a second direction. In a first transistor of the transistors, the first source/drain region is formed between the metal gate electrode of the first transistor and the metal gate electrode of a second transistor of the transistors. The second source/drain region is formed between the metal gate electrode of the first transistor and the dielectric-base dummy gate. A first contact of the first source/drain region is separated from a spacer of the metal gate electrode of the first transistor. A second contact of the second source/drain region is in contact with a spacer of the dielectric-base dummy gate.

An integrated circuit device includes a device layer having devices spaced in accordance with a predetermined device pitch, a first metal interconnection layer disposed above the device layer and coupled to the device layer, and a second metal interconnection layer disposed above the first metal interconnection layer and coupled to the first metal interconnection layer through a first via layer. The second metal interconnection layer has metal lines spaced in accordance with a predetermined metal line pitch, and a ratio of the predetermined metal line pitch to predetermined device pitch is less than 1.

A semiconductor integrated circuit device includes a first power wiring that is formed on a semiconductor substrate and that extends in a first direction, a second power wiring that extends in the first direction such that the second power wiring is separated from the first power wiring, a first diffusion layer that is used for a p-channel type MOSFET and that is formed in a region between the first power wiring and the second power wiring, a second diffusion layer that is used for an n-channel type MOSFET and that is formed on a side of the second power wiring with respect to the first diffusion layer in the region between the first power wiring and the second power wiring, a first gate electrode that extends in a second direction perpendicular to the first direction and that straddles the first diffusion layer, a second gate electrode that extends in the second direction and that straddles the second diffusion layer, and a third diffusion layer for backgates that is formed below at least one of the first power wiring and the second power wiring and that is placed in a dotted manner along the first direction.

A semiconductor structure is disclosed. The semiconductor structure includes: a first standard cell; and a second standard cell; wherein a cell width of the first standard cell along a first direction is substantially the same as a cell width of the second standard cell along the first direction, and a cell height of the first standard cell along a second direction perpendicular to the first direction is substantially greater than a cell height of the second standard cell along the second direction.

In method for forming a semiconductor device, a first opening is formed in a dielectric stack that has a cylinder shape with a first sidewall. A first conductive layer is deposited along the first sidewall of the first opening and a first insulating layer is deposited along an inner sidewall of the first conductive layer. The dielectric stack is then etched along an inner sidewall of the first insulating layer so as to form a second opening that extends into the dielectric stack with a second sidewall. A second conductive layer is further formed along the second sidewall of the second opening and a second insulating layer is formed along an inner sidewall of the second conductive layer. A bottom of the second conductive layer is positioned below a bottom of the first conductive layer to form a staggered configuration.