Abstract: A method of manufacturing a semiconductor device including: arranging a first and a second gate strip separating in a first distance, wherein each of the first and the second gate strip is a gate terminal of a transistor; depositing a first contact via on the first gate strip; forming a first conductive strip on the first contact via, wherein the first conductive strip and the first gate strip are crisscrossed from top view; arranging a second and a third conductive strip, above the first conductive strip, separating in a second distance, wherein each of the second and the third conductive strip is free from connecting to the first conductive strip, the first and the second conductive strip are crisscrossed from top view. The first distance is twice as the second distance. A length of the first conductive strip is smaller than two and a half times as the first distance.

Abstract: A semiconductor structure includes a plurality of cells. Each cell has a plurality of transistors, a plurality of inner metal lines, two first backside power lines and one second backside power line. The inner metal lines, the first backside power lines and the second backside power line are disposed on a back side of the transistors. The inner metal lines, the first backside power lines and the second backside power line extend along a first axis. The second backside power line is disposed between the two first backside power lines. The inner metal lines are electrically connected to the first backside power lines and the transistors, and electrically connected to the second backside power line and the transistors. The cells are arranged along a second axis, the second axis being vertical to the first axis.

Abstract: A semiconductor device includes first, second, and third conductive regions and first and second active regions. The first conductive region has a first width and extends along a first direction. The second conductive region has a second width and extends along the first direction. The first width is greater than the second width. The first active region has a third width and extends along the first direction. The second active region has a fourth width and extends along the first direction. The third width is less than the fourth width. The third conductive region extends along a second direction and is electrically connected to the first conductive region. The second direction is different from the first direction. The first and second active regions are neighboring active regions.

Abstract: Methods and devices are described herein for random cut patterning. A first metal line and a second metal line are formed within a cell of a substrate and extend in a vertical direction. A third metal line and a fourth metal line are formed within the cell and are perpendicular to the first metal line and the second metal line, respectively. A first circular region at one end of the first metal line is formed using a first patterning technique and a second circular region at one end of the second metal line is formed using a second patterning technique. The first circular region is laterally extended using a second patterning technique to form the third metal line and the second circular region is laterally extended using the second patterning technique to form the fourth metal line.

Abstract: A semiconductor structure is disclosed that includes a first conductive line, a first conductive segment, a second conductive segment, and a gate. The first conductive segment is electrically coupled to the first conductive line through a conductive via. The second conductive segment is configured to electrically couple the first conductive segment with a third conductive segment disposed over an active area. The gate is disposed under the second conductive segment and disposed between first conductive segment and the third conductive segment. The first conductive line and the second conductive segment are disposed at two sides of the conductive via respectively. A length of the first conductive segment is greater than a length of the third conductive segment.

Abstract: A method of manufacturing a semiconductor device includes depositing a first material on a substrate, depositing on the substrate a second material that has an etch selectivity different from an etch selectively of the first material, depositing a spacer material on the first and second material, and etching the substrate using the spacer material as an etch mask to form a fin under the first material and a fin under the second material.

Abstract: The present disclosure describes various non-planar semiconductor devices, such as fin field-effect transistors (finFETs) to provide an example, having one or more metal rail conductors and various methods for fabricating these non-planar semiconductor devices. In some situations, the one or more metal rail conductors can be electrically connected to gate, source, and/or drain regions of these various non-planar semiconductor devices. In these situations, the one or more metal rail conductors can be utilized to electrically connect the gate, the source, and/or the drain regions of various non-planar semiconductor devices to other gate, source, and/or drain regions of various non-planar semiconductor devices and/or other semiconductor devices. However, in other situations, the one or more metal rail conductors can be isolated from the gate, the source, and/or the drain regions these various non-planar semiconductor devices.

Abstract: An integrated circuit includes a first pair of power rails and a second pair of power rails that are disposed in a first layer, conductive lines disposed in a second layer above the first layer, and a first active area disposed in a third layer above the second layer. The first active area is arranged to overlap the first pair of power rails. The first active area is coupled to the first pair of power rails through a first line of the conductive lines and a first group of vias, and the first active area is coupled to the second pair of power rails through at least one second line of the conductive lines and a second group of vias different from the first group of vias.

Abstract: An integrated circuit with mixed poly pitch cells with a plurality of different pitch sizes is disclosed. The integrated circuit includes: at least a minimum unit each with at least a first number of first poly pitch cells with a first pitch size, and a second number of second poly pitch cells with a second pitch size, the first pitch size PP is different from the second pitch size PP1, the greatest common divisor of the first pitch size PP and the second pitch size PP1 is GCD, wherein GCD is an integer greater than 1; a gate length of the first pitch size is Lg; a gate length of the second pitch size is Lg1; Lg and Lg1 are capable of being extended to achieve G-bias for power and speed optimization of the minimum unit and the integrated circuit.

Abstract: A semiconductor device includes: a substrate; an ion-implanted silicon layer disposed in the substrate; a first insulator layer disposed over the ion-implanted silicon layer; an active device disposed over the first insulator layer; and a conductive via configured to penetrate the first insulator layer for coupling the ion-implanted silicon layer and the active device.

Abstract: A method (of forming a semiconductor device) including forming cell regions (in alternating first and second rows having first and second heights) including forming a majority of the cell regions in the first rows including: limiting a height of the majority of the cell regions to be single-row cell regions that span corresponding single one of the first rows but do not extend therebeyond; and forming a minority of the cell regions correspondingly in at least the first rows including reducing widths of the multi-row cell regions to be smaller than comparable single-row cell regions; and expanding heights of the minority of the cell regions to be multi-row cell regions, each of the multi-row cell regions spanning a corresponding single first row and at least a corresponding second row such that cell region densities of the second rows are at least about forty percent.

Abstract: An infusion apparatus includes a fixture body, a tube socket and a buckling device. The fixture body has a first and a second ends along a first direction. The fixture body has a through hole. Two first protruding pieces are located at the second end along a second direction perpendicular with the first direction. The fixture body penetrates through and is slidable relative with the tube socket which has two grooves along the second direction. The buckling device includes a machine body and two hooking structures. The machine body has a mounting hole. The hooking structures are disposed at opposite sides of the mounting hole and respectively include a hook and a second protruding piece. The hooks buckle within the grooves. A shortest distance between the second protruding pieces is less than a longest distance between the first protruding pieces.

Abstract: Exemplary embodiments for an exemplary dual transmission gate and various exemplary integrated circuit layouts for the exemplary dual transmission gate are disclosed. These exemplary integrated circuit layouts represent double-height, also referred to as double rule, integrated circuit layouts. These double rule integrated circuit layouts include a first group of rows from among multiple rows of an electronic device design real estate and a second group of rows from among the multiple rows of the electronic device design real estate to accommodate a first metal layer of a semiconductor stack. The first group of rows can include a first pair of complementary metal-oxide-semiconductor field-effect (CMOS) transistors, such as a first p-type metal-oxide-semiconductor field-effect (PMOS) transistor and a first n-type metal-oxide-semiconductor field-effect (NMOS) transistor, and the second group of rows can include a second pair of CMOS transistors, such as a second PMOS transistor and a second NMOS transistor.

Abstract: One aspect of this description relates to a method for operating an integrated circuit (IC) manufacturing system. The method includes placing a first nano-sheet structure within a IC layout diagram. The first nano-sheet structure has a first width. The method includes abutting a second nano-sheet structure with the first nano-sheet structure. The second nano-sheet structure has a second width. The second width is less than the first width. The method includes generating and storing the IC layout diagram in a storage device.

Abstract: Apparatus and methods for generating a physical layout for a high density routing circuit are disclosed. An exemplary semiconductor structure includes: a gate structure; a plurality of first metal lines formed in a first dielectric layer below the gate structure; at least one first via formed in a second dielectric layer between the gate structure and the first dielectric layer; a plurality of second metal lines formed in a third dielectric layer over the gate structure; and at least one second via formed in a fourth dielectric layer between the gate structure and the third dielectric layer. Each of the at least one first via is electrically connected to the gate structure and a corresponding one of the plurality of first metal lines. Each of the at least one second via is electrically connected to the gate structure and a corresponding one of the plurality of second metal lines.

Abstract: A monolithic three-dimensional (3D) integrated circuit (IC) device includes a lower tier including a lower tier cell and an upper tier arranged over the lower tier. The upper tier has a first upper tier cell and a second upper tier cell separated by a predetermined lateral space. A monolithic inter-tier via (MIV) extends from the lower tier through the predetermined lateral space, and the MIV has a first end electrically connected to the lower tier cell and a second end electrically connected to the first upper tier cell.

Abstract: Apparatus and methods for back side routing a data signal in a semiconductor device are described. In one example, a described semiconductor cell structure includes: a dummy device region at a front side of the semiconductor cell structure; a metal layer including a plurality of metal lines at a back side of the semiconductor cell structure; a dielectric layer formed between the dummy device region and the metal layer; an inner metal disposed within the dielectric layer; at least one first via that is formed through the dielectric layer and electrically connects the inner metal to the plurality of metal lines at the back side; and at least one second via that is formed in the dielectric layer and physically coupled between the inner metal and the dummy device region at the front side.

Abstract: A method of manufacturing an integrated circuit (IC) structure includes forming an opening in a first dielectric material between a first gate structure and a second gate structure by removing a portion of the first dielectric material overlying a fin structure; filling at least part of the opening with a second dielectric material; and forming a contact overlying the fin structure and the second dielectric material.

Abstract: A method of forming a semiconductor device includes forming a wafer having an ion-implanted silicon layer, wherein the ion-implanted silicon layer is disposed between a first insulator layer and a second insulator layer inside the wafer; forming an active region over the ion-implanted silicon layer; forming an active device in the active region; and forming a conductive via to couple the ion-implanted silicon layer and the active device.

Abstract: Exemplary embodiments for an exemplary dual transmission gate and various exemplary integrated circuit layouts for the exemplary dual transmission gate are disclosed. These exemplary integrated circuit layouts represent double-height, also referred to as double rule, integrated circuit layouts. These double rule integrated circuit layouts include a first group of rows from among multiple rows of an electronic device design real estate and a second group of rows from among the multiple rows of the electronic device design real estate to accommodate a first metal layer of a semiconductor stack. The first group of rows can include a first pair of complementary metal-oxide-semiconductor field-effect (CMOS) transistors, such as a first p-type metal-oxide-semiconductor field-effect (PMOS) transistor and a first n-type metal-oxide-semiconductor field-effect (NMOS) transistor, and the second group of rows can include a second pair of CMOS transistors, such as a second PMOS transistor and a second NMOS transistor.