Integrated circuit layouts are disclosed that include metal layers with metal tracks having separate metal sections along the metal tracks. The separate metal sections along a single track may be electrically isolated from each other. The separate metal sections may then be electrically connected to different voltage tracks in metal layers above and/or below the metal layer with the separate metal sections. One or more of the metal layers in the integrated circuit layouts may also include metal tracks at different voltages (e.g., power and ground) that are adjacent to each other within a power grid layout. The metal tracks may be separated by electrically insulating material. The metal tracks and the electrically insulating material between the tracks may create capacitance in the power grid layout.

A cell comprising at least one diffusion region and a plurality of interconnection conductive patterns located over the at least one diffusion layer and comprising a first outer interconnection conductive pattern and a second outer interconnection conductive pattern. The cell further includes at least one different conductive pattern located above the at least one diffusion region and interspersed between the plurality of interconnection conductive patterns. The at least one diffusion region extends in a first direction and the plurality of interconnection conductive patterns and at least one different conductive pattern extend in a second direction substantially perpendicular to the first direction. At least one of the interconnection conductive patterns extends in the second direction substantially perpendicular to the first direction and is long enough to connect to another interconnection conductive pattern on a second cell when the cell abuts the second cell vertically to create at least one routing resource.

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.

A local interconnect is formed in contact with an upper surface of an impurity diffusion region and extends to below a potential supply interconnect. A contact hole electrically couples the local interconnect to the potential supply interconnect. The local interconnect, which is formed in contact with the upper surface of the impurity diffusion region, is used for electrically coupling the impurity diffusion region to the potential supply interconnect.

A layout of a standard cell is stored on a non-transitory computer-readable medium and includes a first conductive pattern, a second conductive pattern, a plurality of active area patterns and a first central conductive pattern. The plurality of active area patterns is isolated from each other and arranged in a first row and a second row between the first and second conductive patterns. The first row is adjacent the first conductive pattern and includes a first active area pattern and a second active area pattern among the plurality of active area patterns. The second row is adjacent the second conductive pattern and includes a third active area pattern and a fourth active area pattern among the plurality of active area patterns. The first central conductive pattern is arranged between the first and second active area patterns. The first central conductive pattern overlaps the first conductive pattern.

A vertical field effect transistor (VFET) cell implementing a VFET circuit over a plurality of gate grids includes: a 1.sup.st circuit including at least one VFET and provided over at least one gate grid; and a 2.sup.nd circuit including at least one VFET and provided over at least one gate grid formed on a left or right side of the 1.sup.st circuit, wherein a gate of the VFET of the 1.sup.st circuit is configured to share a gate signal or a source/drain signal of the VFET of the 2.sup.nd circuit, and the 1.sup.st circuit is an (X−1)-contacted poly pitch (CPP) circuit, which is (X−1) CPP wide, converted from an X-CPP circuit which is X CPP wide and performs a same logic function as the (X−1)-CPP circuit, X being an integer greater than 1.

A semiconductor structure includes a power grid layer (including a first metallization layer) and a set of cells. The first metallization layer includes: conductive first and second portions which provide correspondingly a power-supply voltage and a reference voltage, and which have corresponding long axes oriented substantially parallel to a first direction; and conductive third and fourth portions which provide correspondingly the power-supply voltage and the reference voltage, and which have corresponding long axes oriented substantially parallel to a second direction substantially perpendicular to the first direction. The set of cells is located below the PG layer. Each cell is monostate cell which lacks an input signal and has a single output state. The cells are arranged to overlap at least one of the first and second portions in a repeating relationship with respect to at least one of the first or second portions of the first metallization layer.

An IC includes: a plurality of first cells placed in a series of first rows extending in a first horizontal direction and each having a first height; and a plurality of second cells placed in a series of second rows extending in the first horizontal direction and each having a second height different from the first height, wherein a total height of the series of first rows corresponds to a multiple of a height of a first multi-height cell with a maximum height among the plurality of first cells, and a total height of the series of second rows corresponds to a multiple of a height of a second multi-height cell with a maximum height among the plurality of second cells.

A method of forming an integrated circuit is disclosed. The method includes generating, by a processor, a layout design of the integrated circuit, outputting the integrated circuit based on the layout design, and removing a portion of a conductive structure of the integrated circuit to form a first conductive structure and a second conductive structure. Generating the layout design includes generating a standard cell layout having a set of conductive feature layout patterns, placing a power layout pattern with the standard cell layout according to at least one design criterion, and extending at least one conductive feature layout pattern of the set of conductive feature layout patterns in at least one direction to a boundary of the power layout pattern. The power layout pattern includes a cut feature layout pattern. The cut feature layout pattern identifies a location of the removed portion of the conductive structure of the integrated circuit.

An integrated circuit including first and second macroblocks arranged in a first direction, and a plurality of cells between the first macroblock and the second macroblock, the plurality of cells including at least one first ending cell adjacent to the first macroblock and having a first width in the first direction, at least one second ending cell adjacent to the second macroblock and having a second width different from the first width in the first direction, and at least one standard cell between the at least one first ending cell and the at least one second ending cell may be provided.