Abstract: A method includes creating a layout design of the integrated circuit after determining a difference between the poly extension effect of a p-type transistor and the poly extension effect of an n-type transistor. Creating the layout design includes forming first-type active zone patterns, forming second-type active zone patterns, generating a gate-strip pattern, and positioning the gate-strip pattern over the first-type active zone patterns and the second-type active zone patterns. Creating the layout design also includes determining whether to generate one or more poly cut patterns that intersect the gate-strip, based on the difference between the poly extension effect of a p-type transistor and the poly extension effect of an n-type transistor.

Abstract: Systems, methods and devices are provided, which can include an engineering change order (ECO) base. A base layout cell includes metal layer regions, conductive gate patterns arranged above metal layer regions; oxide definition (OD) patterns, metal-zero layer over oxide-definition (metal-zero) patterns, at least one cut metal layer (CMD) pattern; and at least one via region. The base layout cell can be implemented in at least two non-identical functional cells. A first functional cell of the at least two non-identical functional cells includes first interconnection conductive patterns arranged connecting metal-zero structures corresponding to at least two metal-zero patterns in a first layout, and a second functional cell of the at least two non-identical functional cells includes second interconnection conductive patterns arranged connecting metal-zero structures corresponding to at least two metal-zero patterns in a second layout.

Abstract: Mechanisms are provided for scheduling a workload in a cloud computing system. A cloud affinity factor (CAF) computer model is trained, via a machine learning process based on a training dataset comprising static characteristics of a workload binary for a workload, and dynamic characteristics corresponding to historical performance data for the workload, such that the trained CAF computer model predicts a performance classification for a given workload binary. The trained CAF computer model processes a new workload to generate a performance classification for the new workload. Cloud affinity factor(s) are generated based on the performance classification for the new workload. Node affinity and dispatch rule(s) are applied to the cloud affinity factor(s) to select one or more nodes of the cloud computing system to which to dispatch the workload. The workload is then scheduled on the selected one or more nodes.

Abstract: A catalyst for continuous production of 1,1,1,3-tetrachloropropane through gas-solid reaction as well as a preparation method and use thereof are provided. The catalyst includes a zero-valent iron and phosphorus co-modified carbon material which includes a carbon material as a carrier, a zero-valent iron supported onto the carrier and serving as an active component, and a phosphate functional group formed on the surface of the carbon material. The preparation method includes: co-modifying a carbon material using a ferric salt and organic phosphorus to obtain the catalyst for continuous production of 1,1,1,3-tetrachloropropane through gas-solid reaction. The present application further provides a method for continuous production of 1,1,1,3-tetrachloropropane through gas-solid reaction.

Abstract: An integrated circuit includes a first power rail and a second power rail extending in a first direction, and a first power grid stub connected to the first power rail through a first via-connector. The integrated circuit also includes a first vertical conducting line extending in a second direction in a circuit cell between a first vertical cell boundary and a second vertical cell boundary. The first vertical conducting line and the first power grid stub are in a same metal layer and aligned with each other along the second direction.

Abstract: Provided is an elliptical multi-mesa laser structure, including a substrate layer, an N-DBR, a functional layer and a P-DBR sequentially arranged from bottom to top. The substrate layer is fixedly connected with an N contact layer. The N-DBR is fixedly connected to a top of the substrate layer, and the N contact layer is arranged around the N-DBR. A space layer is inserted in the N-DBR. The functional layer is fixedly connected to a top of the N-DBR. The P-DBR is fixedly connected to a top of the functional layer, and a top of the P-DBR is fixedly connected with a P contact layer. Another space layer is inserted into the P-DBR.

Abstract: An integrated circuit is provided and includes a multi-bit cell having multiple bit cells disposed in multiple cell rows. The bit cells include M bit cells, M being positive integers. A first bit cell of the bit cells and a M-th bit cell of the bit cells are arranged diagonally in different cell rows in the multi-bit cell. The multi-bit cell includes first to fourth cell boundaries. The first and second boundaries extend in a first direction and the third and fourth boundaries extend in a second direction different from the first direction. The first bit cell and a second bit cell of the bit cells abut the third cell boundary, and the first bit cell and a (M/2+1)-th bit cell of the bit cells abut the first cell boundary.

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: A method for forming a semiconductor device includes: forming a fin structure protruding from a substrate of the semiconductor device; forming a first conductive rail on the substrate, wherein a side of the first conductive rail facing the fin structure has a first recess and a second recess; forming a first conductive line in a same layer as the first conductive rail by filling a first conductive material into the first recess, wherein the first conductive line extends across the fin structure and wraps a portion of the fin structure; and forming a second conductive line in the same layer as the first conductive rail by filling a second conductive material into the second recess, wherein the second conductive line extends across the fin structure and contacts another portion of the fin structure.

Abstract: A layout method includes disposing a first conductive path and a second conductive path across a boundary between a first layout device and a second layout device abutting the first layout device. The layout method also includes disposing a first cut layer on the first conductive path nearby the boundary, and disposing a second cut layer on the second conductive path nearby the boundary. The layout method also includes moving the first cut layer to align with the second cut layer.

Abstract: A semiconductor structure includes a first transistor, a second transistor, a first dummy source/drain, a third transistor, a fourth transistor, and a second dummy source/drain. The first transistor and a second transistor adjacent to the first transistor are at a first elevation. The first dummy source/drain is disposed at the first elevation. The third transistor and a fourth transistor adjacent to the third transistor, are at a second elevation different from the first elevation. The second dummy source/drain is disposed at the second elevation. The second transistor is vertically aligned with the third transistor. The first dummy source/drain is vertically aligned with a source/drain of the fourth transistor. The second dummy source/drain is vertically aligned with a source/drain of the first transistor. The gate structure between the second dummy source/drain and a source/drain of the third transistor is absent. A method for manufacturing a semiconductor structure is also provided.

Abstract: A flip-flop includes a first, second, third and a fourth active region extending in a first direction, and being on a first level of a substrate. The first active region corresponds to a first set of transistors of a first type. The second active region corresponds to a second set of transistors of a second type different from the first type. The third active region corresponds to a third set of transistors of the second type. The fourth active region corresponds to a fourth set of transistors of the first type. The flip-flop further includes a first gate structure extending in the second direction, overlapping at least the second active region and the third active region, and being on a second level different from the first level. The first gate structure is configured to receive a first clock signal.

Abstract: An integrated circuit includes a first cell and a second cell. The first cell has a first height along a first direction. The second cell has a second height shorter than the first height along the first direction. A transistor of the first cell and a transistor of the second cell share a first active area, and a first boundary of the first cell, a first boundary of the second cell, a second boundary of the first cell and a second boundary of the second cell are arranged in order along the first direction.

Abstract: A method of making a semiconductor device includes forming a first active region on a first side of a substrate. The method further includes forming a first source/drain (S/D) electrode surrounding a first portion of the first active region. The method further includes forming an S/D connect via extending through the substrate. The method further includes flipping the substrate. The method further includes forming a second active region on a second side of the substrate, wherein the second side of the substrate is opposite to the first side of the substrate. The method further includes forming a second S/D electrode surrounding a first portion of the second active region, wherein the S/D connect directly contacts both the first S/D electrode and the second S/D electrode.

Abstract: Systems and methods for an integrated circuit layout is disclosed. The integrated circuit layout includes a first block including multiple first cells, each of which has a first cell height, and a second block including multiple second cells, each of which has a second cell height. The first block is disposed next to the second block with a spacing that is either equal to zero or less than any of the first or second cell heights.

Abstract: An integrated circuit includes a first transistor of a first conductivity type including a first active area extending in a first direction; a second transistor of the first conductivity type including at least two second active areas extending in the first direction and a first gate stripe crossing the at least two second active areas; and a third transistor of a second conductivity type that is stacked on the second transistor and includes at least two third active areas arranged above the at least two second active areas. A top most boundary line of the first active area is aligned with a top most boundary line of one of the at least two third active areas in a layout view.

Abstract: A clock gating circuit includes a NOR logic gate, a transmission gate, a cross-coupled pair of transistors, and a first transistor. The NOR logic gate is coupled to a first node, and receives a first and a second enable signal, and outputs a first control signal. The transmission gate is coupled between the first and a second node, and receives the first control signal, an inverted clock input signal and a clock output signal. The cross-coupled pair of transistors is coupled between the second node and an output node, and receives at least a second control signal. The first transistor includes a first gate terminal configured to receive the inverted clock input signal, a first drain terminal coupled to the output node, and a first source terminal coupled to a reference voltage supply. The first transistor adjusts the clock output signal responsive to the inverted clock input signal.

Abstract: Systems, methods and devices are provided, which can include an engineering change order (ECO) base. A base layout cell includes metal layer regions, conductive gate patterns arranged above metal layer regions; oxide definition (OD) patterns, metal-zero layer over oxide-definition (metal-zero) patterns, at least one cut metal layer (CMD) pattern; and at least one via region. The base layout cell can be implemented in at least two non-identical functional cells. A first functional cell of the at least two non-identical functional cells includes first interconnection conductive patterns arranged connecting metal-zero structures corresponding to at least two metal-zero patterns in a first layout, and a second functional cell of the at least two non-identical functional cells includes second interconnection conductive patterns arranged connecting metal-zero structures corresponding to at least two metal-zero patterns in a second layout.

Abstract: An integrated circuit includes a first and second active region, a first insulating region, and a first and second contact. The first and second active regions extend in a first direction, are in a substrate, and are located on a first level. The first active region includes a first drain/source region and a second drain/source region. The second active region includes a third drain/source region. The first insulating region is over the first drain/source region. The first contact extends in a second direction, overlaps the third drain/source region, is electrically coupled to the third drain/source region and is located on a second level. The second contact extends in at least the second direction, overlaps the first insulating region and the first contact. The second contact is electrically insulated from the first drain/source region, is electrically coupled to the third drain/source region, and is located on a third level.

Abstract: An integrated circuit device includes a first power rail, a first active area extending in a first direction, and a plurality of gates contacting the first active area and extending in a second direction perpendicular to the first direction. A first transistor includes the first active area and a first one of the gates. The first transistor has a first threshold voltage (VT). A second transistor includes the first active area and a second one of the gates. The second transistor has a second VT different than the first VT. A tie-off transistor is positioned between the first transistor and the second transistor, and includes the first active area and a third one of the gates, wherein the third gate is connected to the first power rail.