Gate structures formed from substantially rectangular shaped gate structure layout shapes positioned on a gate horizontal grid having at least seven gate gridlines within a region. A first-metal layer including first-metal structures formed from substantially rectangular shaped first-metal structure layout shapes is formed above top surfaces of the gate structures within the region. The first-metal structure layout shapes are positioned on a first-metal vertical grid having at least eight first-metal gridlines. At least six contact structures are formed from substantially rectangular shaped contact structure layout shapes in physical and electrical contact with corresponding ones of at least six of the gate structures. A total number of first-transistor-type-only gate structures equals a total number of second-transistor-type-only gate structures within the region. At least four transistors of a first transistor type and at least four transistors of a second transistor type collectively form part of a logic circuit within the region.

Gate structures are positioned within a region in accordance with a gate horizontal grid that includes at least seven gate gridlines separated from each other by a gate pitch of less than or equal to about 193 nanometers. Each gate structure has a substantially rectangular shape with a width of less than or equal to about 45 nanometers and is positioned to extend lengthwise along a corresponding gate gridline. Each gate gridline has at least one gate structure positioned thereon. A first-metal layer is formed above top surfaces of the gate structures within the region and includes first-metal structures positioned in accordance with a first-metal vertical grid that includes at least eight first-metal gridlines. Each first-metal structure has a substantially rectangular shape and is positioned to extend along a corresponding first-metal gridline. At least six contact structures of substantially rectangular shape contact the at least six gate structures.

Gate structures are positioned within a region in accordance with a gate horizontal grid that includes at least seven gate gridlines separated from each other by a gate pitch of less than or equal to about 193 nanometers. Each gate structure has a substantially rectangular shape with a width of less than or equal to about 45 nanometers and is positioned to extend lengthwise along a corresponding gate gridline. Each gate gridline has at least one gate structure positioned thereon. A first-metal layer is formed above top surfaces of the gate structures within the region and includes first-metal structures positioned in accordance with a first-metal vertical grid that includes at least eight first-metal gridlines. Each first-metal structure has a substantially rectangular shape and is positioned to extend along a corresponding first-metal gridline. At least six contact structures of substantially rectangular shape contact the at least six gate structures.

A first transistor has a gate electrode formed by a substantially linear portion of a first conductive structure. A second transistor has a gate electrode formed by a substantially linear portion of a second conductive structure. A third transistor has a gate electrode formed by a substantially linear portion of a third conductive structure. A fourth transistor has a gate electrode formed by a substantially linear portion of a fourth conductive structure. The substantially linear portions of the first, second, third, and fourth conductive structures extend in a first direction and are positioned in accordance with a gate pitch. Gate electrodes of the first and second transistors have a first size as measured in the first direction. Gate electrodes of the third and fourth transistors have a second size as measured in the first direction. The first size is at least two times the second size.

The present disclosure attempts to provide a capacitor cell having a large capacitance value per unit area in a semiconductor integrated circuit device using a three-dimensional transistor device. A logic cell includes a three-dimensional transistor device. A capacitor cell includes a three-dimensional transistor device. A length of a portion, of a local interconnect, which protrudes from a three-dimensional diffusion layer in a direction away from a power supply interconnect in the capacitor cell is greater than a length of a portion, of a local interconnect, which protrudes from a three-dimensional diffusion layer in a direction away from a power supply interconnect in the logic cell.

A first conductive structure forms a gate electrode of a first transistor of a first transistor type. A second conductive structure forms gate electrodes of both a second transistor of the first transistor type and a first transistor of a second transistor type. A third conductive structure forms a gate electrode of a second transistor of the second transistor type. A fourth conductive structure forms gate electrodes of both a third transistor of the first transistor type and a third transistor of the second transistor type. Gate electrodes of the first and second transistors of the first transistor type are separated by a fixed pitch, as are the gate electrodes of the second and third transistors of the second transistor type. The gate electrodes of the first transistor of the first transistor type and the second transistor of the second transistor type are separated by at least the fixed pitch.

A layout structure of a standard cell using a complementary FET (CFET) is provided. First and second transistors that are three-dimensional transistors lie between first and second power supply lines as viewed in plan, the second transistor being formed above the first transistor in the depth direction. A first local interconnect is connected with the source or drain of the first transistor, and a second local interconnect is connected with the source or drain of the second transistor. The first and second local interconnects extend in the Y direction, overlap each other as viewed in plan, and both overlap the first and second power supply lines as viewed in plan.

A method includes fabricating a first-voltage underlayer power rail conductively connecting to the source region of a first-type transistor and fabricating a second-voltage underlayer power rail conductively connecting to the source region of a second-type transistor. Each of the first-voltage and second-voltage underlayer power rails extends in a first direction. The method also includes patterning a first connection layer to form a first-voltage power rail and a second-voltage power rail extending in the second direction which is perpendicular to the first direction. The first-voltage power rail is directly connected with the first-voltage underlayer power rail through a first via-connector and the second-voltage power rail is directly connected with the second-voltage underlayer power rail through a second via-connector.

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 a first-voltage underlayer power rail and a second-voltage underlayer power rail extending in a first direction below a first connection layer. A first-type transistor and a second-type transistor are underneath the first connection layer. The source region of the first-type transistor is connected to the first-voltage underlayer power rail, and the source region of the second-type transistor is connected to the second-voltage underlayer power rail. The integrated circuit also includes a first-voltage power rail, a second-voltage power rail, and a signal conducting line, each of which extends in a second direction in the first connection layer. The first-voltage power rail is connected to the first-voltage underlayer power rail, and the second-voltage power rail is connected to the second-voltage underlayer power rail. The signal conducting line is conductively connected to either a terminal-conductor or a gate-conductor.