Abstract: A process of forming an integrated circuit containing elongated contacts which connect to three active areas and/or MOS gates, and elongated contacts which connect to two active areas and/or MOS gates and directly connect to a first level interconnect, using a litho-freeze-litho-etch process for a contact etch mask. A process of forming an integrated circuit containing elongated contacts which connect to three active areas and/or MOS gates, and elongated contacts which connect to two active areas and/or MOS gates and directly connect to a first level interconnect, using a litho-freeze-litho-etch process for a first level interconnect trench etch mask. A process of forming the integrated circuit using a litho-freeze-litho-etch process for a contact etch mask and a litho-freeze-litho-etch process for a first level interconnect trench etch mask.

Abstract: An integrated circuit with a SAR SRAM cell with power routed in metal-1. An integrated circuit with a SAR SRAM cell that has power routed in Metal-1 and has metal-1 and metal-2 integrated circuit and SAR SRAM cell patterns which are DPT compatible. A process of forming an integrated circuit with a SAR SRAM cell with DPT compatible integrated circuit and SAR SRAM cell metal-1 and metal-2 patterns.

Abstract: An integrated circuit with an active geometry with a wide active region and with a narrow active region with at least one jog where said wide active region transitions to said narrow active region and where a gate overlies said jog. A method of making an integrated circuit with an active geometry with a wide active region and with a narrow active region with at least one jog where said wide active region transitions to said narrow active region, where a gate overlies said jog and where a gate overlies the wide active region forming a wide transistor.

Abstract: An integrated circuit with an active geometry with a wide active region and with a narrow active region with at least one jog where said wide active region transitions to said narrow active region and where a gate overlies said jog. A method of making an integrated circuit with an active geometry with a wide active region and with a narrow active region with at least one jog where said wide active region transitions to said narrow active region, where a gate overlies said jog and where a gate overlies the wide active region forming a wide transistor.

Abstract: A method of generating an integrated circuit with a double patterning technology (DPT) compatible via pattern using a reduced DPT compatible via design rule set. A reduced DPT compatible via design rule set. A method of forming an integrated circuit using a via pattern generated from a reduced DPT compatible design rule set.

Abstract: A process of forming an integrated circuit containing elongated contacts which connect to three active areas and/or MOS gates, and elongated contacts which connect to two active areas and/or MOS gates and directly connect to a first level interconnect, using a litho-freeze-litho-etch process for a contact etch mask. A process of forming an integrated circuit containing elongated contacts which connect to three active areas and/or MOS gates, and elongated contacts which connect to two active areas and/or MOS gates and directly connect to a first level interconnect, using a litho-freeze-litho-etch process for a first level interconnect trench etch mask. A process of forming the integrated circuit using a litho-freeze-litho-etch process for a contact etch mask and a litho-freeze-litho-etch process for a first level interconnect trench etch mask.

Abstract: An integrated circuit containing elongated contacts, including elongated contacts which connect to at least three active areas and/or MOS gates, and including elongated contacts which connect to exactly two active areas and/or MOS gates and directly connect to a first level interconnect. A process of forming an integrated circuit containing elongated contacts, including elongated contacts which connect to at least three active areas and/or MOS gates, using exactly two contact photolithographic exposure operations, and including elongated contacts which connect to exactly two active areas and/or MOS gates and directly connect to a first level interconnect.

Abstract: An integrated circuit with an MOS transistor abutting field oxide and a gate structure on the field oxide adjacent to the MOS transistor and a gap between an epitaxial source/drain and the field oxide is formed with a silicon dioxide-based gap filler in the gap. Metal silicide is formed on the exposed epitaxial source/drain region. A CESL is formed over the integrated circuit and a PMD layer is formed over the CESL. A contact is formed through the PMD layer and CESL to make an electrical connection to the metal silicide on the epitaxial source/drain region.

Abstract: An integrated circuit may be formed by forming a first interconnect pattern in a first plurality of parallel route tracks, and forming a second interconnect pattern in a second plurality of parallel route tracks, in which the second plurality of route tracks are alternated with the first plurality of route tracks. The first interconnect pattern includes a first lead pattern and the second interconnect pattern includes a second lead pattern, such that the route track containing the first lead pattern is immediately adjacent to the route track containing the second lead pattern. Metal interconnect lines are formed in the first interconnect pattern and the second interconnect pattern. A stretch crossconnect is formed in a vertical connecting level, such as a via or contact level, which electrically connects only the first lead and the second lead. The stretch crossconnect is formed concurrently with other vertical interconnect elements.

Abstract: A method of forming PMOS transistors. A SiGe cavity formation process includes cavity etching a structure including a gate stack having a gate electrode on a gate dielectric on a substrate, a sidewall spacer, and a hardmask layer on the gate electrode. The cavity etching includes (i) a first anisotropic dry etch for etching through the hardmask layer lateral to the gate stack and beginning a recessed cavity in the substrate, (ii) a dry lateral etch, and (iii) a second anisotropic dry etch. A wet crystallographic etch completes formation of the recessed cavity. A customized time is calculated for a selected dry etch step from the plurality of dry etch steps based on in-process SiGe cavity data for a measured cavity parameter for a SiGe cavity formation process. The customized time for the selected dry etch is used to cavity etch at least one substrate in a lot or run.

Abstract: An integrated circuit with standard cells with top and bottom metal-1 and metal-2 power rails and with lateral standard cell borders that lie between an outermost vertical dummy poly lead from one standard cell and an adjacent standard cell. A DPT compatible standard cell design rule set. A method of forming an integrated circuit with standard cells constructed using a DPT compatible standard cell design rule set. A method of forming DPT compatible standard cells.

Abstract: A method and apparatus for designing a lithography mask set which provides polygon features of a desired size at advanced technology nodes, for example, using live features and dummy features. A dummy feature can be formed within a confined space by specifying an allowable dummy feature length even though the feature length may result in contact between the dummy feature and the live feature. After specifying the dummy feature length, a pattern generation (PG) extract can be performed to pull back the dummy feature away from the live feature by an allowable distance. The PG exact process can result in a shorter dummy feature which has a length which is shorter than can be specified directly by design rules, but which passes rule checking.

Abstract: A process of generating design rules, OPC rules and optimizing illumination source models for an integrated circuit layout, to form short lines, terminated lines and crossovers between adjacent parallel route tracks, may include the steps of generating a set of template structures which use a set of characteristic design rules, and performing a plurality of source mask optimization (SMO) operations on the set of template structures with different values for the design rules in each SMO operation. In a first embodiment, the SMO operations are run using a predetermined set of values for each of the design rules, spanning a desired range of design rule values. In a second embodiment, the SMO operations are performed in a conditional iterative process in which values of the design rules are adjusted after each iteration based on results of the iteration.

Abstract: A method of fabricating gate level electrodes and interconnects in an integrated circuit, and an integrated circuit so fabricated, with improved process margin for the gate level interconnects of a width near the critical dimension. Off-axis illumination, as used in the photolithography of deep sub-micron critical dimension, is facilitated by the patterned features having a preferred orientation in a common direction, with a pitch constrained to within a relatively narrow range. Interconnects in that same gate level, for example “field poly” interconnects, that run parallel to an array of gate elements are placed within a specified distance range from the ends of the gate elements, or at a distance sufficient to allow sub-resolution assist features.

Abstract: A method of generating an integrated circuit with a DPT compatible interconnect pattern using a reduced DPT compatible design rule set and color covers. A method of operating a computer to generate an integrated circuit with a DPT compatible interconnect pattern using a reduced DPT compatible design rule set and using color covers. A reduced DPT compatible design rule set.

Abstract: A process of generating design rules, OPC rules and optimizing illumination source models for an integrated circuit layout, to form short lines, terminated lines and crossovers between adjacent parallel route tracks, may include the steps of generating a set of template structures which use a set of characteristic design rules, and performing a plurality of source mask optimization (SMO) operations on the set of template structures with different values for the design rules in each SMO operation. In a first embodiment, the SMO operations are run using a predetermined set of values for each of the design rules, spanning a desired range of design rule values. In a second embodiment, the SMO operations are performed in a conditional iterative process in which values of the design rules are adjusted after each iteration based on results of the iteration.

Abstract: A method of forming an IC including MOS transistors includes using a gate mask to form a first active gate feature having a line width W1 over an active area and a neighboring dummy feature having a line width 0.8 W1 to 1.3 W1. The neighboring dummy feature has a first side adjacent to the first active gate feature, and a nearest gate level feature on a second side opposite the first side. The neighboring dummy feature defines a gate pitch based on a distance to the first active gate feature or the neighboring dummy feature maintains a gate pitch in a gate array including the first active gate feature. The spacing between the neighboring dummy feature and the nearest gate level feature (i) maintains the gate pitch or (ii) provides a SRAF enabling distance that is ?2 times the gate pitch and the gate mask includes a SRAF over the SRAF distance.

Abstract: A method of forming an IC including MOS transistors includes using a gate mask to form a first active gate feature having a line width W1 over an active area and a neighboring dummy feature having a line width 0.8 W1 to 1.3 W1. The neighboring dummy feature has a first side adjacent to the first active gate feature, and a nearest gate level feature on a second side opposite the first side. The neighboring dummy feature defines a gate pitch based on a distance to the first active gate feature or the neighboring dummy feature maintains a gate pitch in a gate array including the first active gate feature. The spacing between the neighboring dummy feature and the nearest gate level feature (i) maintains the gate pitch or (ii) provides a SRAF enabling distance that is ?2 times the gate pitch and the gate mask includes a SRAF over the SRAF distance.

Abstract: An integrated circuit may be formed by forming a first interconnect pattern in a first plurality of parallel route tracks, and forming a second interconnect pattern in a second plurality of parallel route tracks, in which the second plurality of route tracks are alternated with the first plurality of route tracks. The first interconnect pattern includes a first lead pattern and the second interconnect pattern includes a second lead pattern, such that the route track containing the first lead pattern is immediately adjacent to the route track containing the second lead pattern. Metal interconnect lines are formed in the first interconnect pattern and the second interconnect pattern. A stretch crossconnect is formed in a vertical connecting level, such as a via or contact level, which electrically connects only the first lead and the second lead. The stretch crossconnect is formed concurrently with other vertical interconnect elements.

Abstract: An improved method for optimizing layer registration during lithography in the fabrication of a semiconductor device is disclosed. In one example, the method comprises optimizing contact layer registration of an SRAM device having a plurality of transistors having active and gate region features extending generally along a channel length (X) direction and a channel width (Y) direction, respectively. The method comprises aligning a contact layer to a gate layer in the channel length direction (X), using gate layer overlay marks to control the alignment of the contact layer in the channel length direction (X) of the semiconductor device. The method further includes aligning the contact layer to an active layer in the channel width direction (Y), using active layer overlay marks to control the alignment of the contact layer in the channel width direction (Y) of the semiconductor device.