A method for producing a 3D semiconductor device including: providing a first level including a first single crystal layer; forming peripheral circuitry in and/or on the first level, and includes first single crystal transistors; forming a first metal layer on top of the first level; forming a second metal layer on top of the first metal layer; forming second level disposed on top of the second metal layer; performing a first lithography step; forming a third level on top of the second level; performing a second lithography step; processing steps to form first memory cells within the second level and second memory cells within the third level, where the plurality of first memory cells include at least one second transistor, and the plurality of second memory cells include at least one third transistor; and deposit a gate electrode for second and third transistors simultaneously.

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.

A 3D semiconductor device, the device comprising: a first level comprising a first single crystal layer, said first level comprising first transistors, wherein each of said first transistors comprises a single crystal channel; first metal layers interconnecting at least said first transistors; a second metal layer overlaying said first metal layers; and a second level comprising a second single crystal layer, said second level comprising second transistors, wherein said second level overlays said first level, wherein at least one of said second transistors comprises a gate all around structure, wherein said second level is directly bonded to said first level, and wherein said bonded comprises direct oxide to oxide bonds.

Integrated circuits including an integrated standard cell structure are provided. In an embodiment, an integrated circuit includes a first transistor gated by a first input and connected to a first power supply rail and an output, a second transistor gated by a second input and connected to the first power supply rail and the output, a floating third transistor and a fourth transistor that are connected to the first power supply rail and a third power supply rail, a fifth transistor gated by the first input and connected to a second power supply rail, a sixth transistor gated by the second input and connected to the second power supply rail, a seventh transistor gated by the second input and connected to the fifth transistor and the output, and an eighth transistor gated by the first input and connected to the sixth transistor and the output.

The present disclosure describes an example method for routing a standard cell with multiple pins. The method can include modifying a dimension of a pin of the standard cell, where the pin is spaced at an increased distance from a boundary of the standard cell than an original position of the pin. The method also includes routing an interconnect from the pin to a via placed on a pin track located between the pin and the boundary and inserting a keep out area between the interconnect and a pin from an adjacent standard cell. The method further includes verifying that the keep out area separates the interconnect from the pin from the adjacent standard cell by at least a predetermined distance.

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.

A semiconductor device includes a substrate having cell areas and power areas that are alternately arranged in a second direction. Gate structures extend in the second direction. The gate structures are spaced apart from each other in a first direction perpendicular to the second direction. Junction layers are arranged at both sides of each gate structure. The junction layers are arranged in the second direction such that each of the junction layer has a flat portion that is proximate to the power area. Cutting patterns are arranged in the power areas. The cutting patterns extend in the first direction such that each of the gate structures and each of the junction layers in neighboring cell areas are separated from each other by the cutting pattern.

A semiconductor device includes a substrate, a front side circuit disposed over a front surface of the substrate, and a backside power delivery circuit disposed over a back surface and including a back side power supply wiring coupled to a first potential. The front side circuit includes semiconductor fins and a first front side insulating layer covering bottom portions of the semiconductor fins, a plurality of buried power supply wirings embedded in the first front side insulating layer, the plurality of buried power supply wirings including a first buried power supply wiring and a second buried power supply wiring, and a power switch configured to electrically connect and disconnect the first buried power supply wiring and the second buried power supply wiring. The second buried power supply wiring is connected to the back side power supply wiring by a first through-silicon via passing through the substrate.

An IC is provided. The IC includes a plurality of a plurality of P-type fin field-effect transistors (FinFETs). The P-type FinFETs includes at least one first P-type FinFET and at least one second P-type FinFET. Source/drain regions of the first P-type FinFET have a first depth, and source/drain regions of the second P-type FinFET have a second depth that is different from the first depth. A first semiconductor fin of the first P-type FinFET includes a first portion and a second portion that are formed by different materials, and the second portion of the first semiconductor fin has a third depth that is greater than the first depth.

A 3D semiconductor device including: a first level including a single crystal silicon layer and a plurality of first transistors each including a single crystal channel; a first metal layer overlaying the plurality of first transistors; a second metal layer overlaying the first metal layer; a third metal layer overlaying the second metal layer; a second level, where the second level overlays the first level and includes a plurality of second transistors; a fourth metal layer overlaying the second level; and a connective path between the fourth metal layer and either the third metal layer or the second metal layer, where the connective path includes a via disposed through the second level and has a diameter of less than 500 nm and greater than 5 nm, where the third metal layer is connected to provide a power or ground signal to at least one of the second transistors.