Abstract: One integrated circuit (IC) product disclosed herein includes a first conductive source/drain contact structure of a first transistor and an insulating source/drain cap positioned above at least a portion of an upper surface of the first conductive source/drain contact structure. In one example, the product also includes a gate-to-source/drain (GSD) contact structure that is conductively coupled to the first conductive source/drain contact structure and a first gate structure of a second transistor, wherein an upper surface of the GSD contact structure is positioned at a first level that is at a level above the upper surface of the first conductive source/drain contact structure, and a CB gate contact structure that is conductively coupled to a second gate structure of a third transistor, wherein an upper surface of the CB gate contact structure is positioned at a level that is above the first level.

Abstract: One illustrative 6T SRAM cell structure disclosed herein includes a first active region with a first N-type pass gate transistor, a first N-type pull-down transistor and a first P-type pull-up transistor, each of which are formed in and above the first active region, wherein the first N-type pull-down transistor is positioned laterally between the first N-type pass gate transistor and the first P-type pull-up transistor, and a second active region with a second N-type pass gate transistor, a second N-type pull-down transistor and a second P-type pull-up transistor, each of which are formed in and above the second active region, wherein the second N-type pull-down transistor is positioned laterally between the second N-type pass gate transistor and the second P-type pull-up transistor.

Abstract: One illustrative method disclosed includes, among other things, selectively forming a gate-to-source/drain (GSD) contact opening and a CB gate contact opening in at least one layer of insulating material and forming an initial gate-to-source/drain (GSD) contact structure and an initial CB gate contact structure in their respective openings, wherein an upper surface of each of the GSD contact structure and the CB gate contact structure is positioned at a first level, and performing a recess etching process on the initial GSD contact structure and the initial CB gate contact structure to form a recessed GSD contact structure and a recessed CB gate contact structure, wherein a recessed upper surface of each of these recessed contact structures is positioned at a second level that is below the first level.

Abstract: An IC product disclosed herein includes a first merged doped source/drain (MDSD) region having an upper surface, a first side surface and a second side surface that intersect one another at a corner of the first merged doped source/drain region, a second MDSD region and a contact trench in an isolation structure positioned between the first and second MDSD regions. The product also includes a conductive gate structure positioned above at least the second MDSD region and a cross-coupled contact structure that comprises a first portion positioned within the contact trench laterally adjacent to and conductively coupled to at least one of the first side surface and the second side surface, and a second portion that is positioned above and conductively coupled to the upper surface of the MDSD region, wherein the cross-coupled contact structure is conductively coupled to the conductive gate structure.

Abstract: One illustrative method disclosed includes, among other things, forming an initial gate-to-source/drain (GSD) contact structure and an initial CB gate contact structure, wherein an upper surface of each of these contact structures are positioned at a first level. In one example, this method also includes forming a masking layer that covers the initial CB gate contact structure and exposes the initial GSD contact structure and, with the masking layer in position, performing a recess etching process on the initial GSD contact structure so as to form a recessed GSD contact structure, wherein a recessed upper surface of the recessed GSD contact structure is positioned at a second level that is below the first level.

Abstract: A method includes forming a first gate structure above a first region of a semiconducting substrate. A first sidewall spacer is formed adjacent the first gate structure. The first gate structure and the first sidewall spacer are recessed to define a first gate contact cavity. A second sidewall spacer is formed in the first gate contact cavity. A first conductive gate contact is formed in the first gate contact cavity. The second sidewall spacer is removed to define a first spacer cavity. A conductive material is formed in the first spacer cavity to form a first conductive spacer contacting the first conductive gate contact.

Abstract: In a method of forming a structure with field effect transistors (FETs) having different drive currents, a stack is formed on a substrate. The substrate is a first semiconductor material and the stack includes alternating layers of a second and the first semiconductor material. Recess(es) filled with sacrificial material are formed in certain area(s) of the stack. The stack is patterned into fins and gate-all-around (GAA) FET processing is performed. GAAFET processing includes removing sacrificial gates to form gate openings for GAAFETs and removing the second semiconductor material and any sacrificial material (if present) from the gate openings such that, within each gate opening, nanoshape(s) that extend laterally between source/drain regions remain. Gate openings for GAAFETs where sacrificial material was removed will have fewer nanoshapes than other gate openings. Thus, in the structure, some GAAFETs will have fewer channel regions and, thereby lower drive currents than others.

Abstract: Disclosed are an in-kerf test structure and testing method for testing an on-chip device. The structure includes at least one test component with at least one test device and adjoining dummy devices connected to the test device. Each adjoining dummy device has proximal node(s) directly connected to a test device and distal node(s) that are not directly connected to a test device. The nodes of each test device and the distal nodes of each adjoining dummy device are connected to input/output pads. During testing the input/output pads are used to bias the nodes of a selected test device as well as the distal node(s) of any adjoining dummy device. By biasing the distal node(s) of an adjoining dummy device, random accumulation of potential thereon is avoided and current contributions from the adjoining dummy device(s) to a current measurement taken from the selected test device can be accurately determined.

Abstract: Disclosed are an in-kerf test structure and testing method for testing an on-chip device. The structure includes at least one test component with at least one test device and adjoining dummy devices connected to the test device. Each adjoining dummy device has proximal node(s) directly connected to a test device and distal node(s) that are not directly connected to a test device. The nodes of each test device and the distal nodes of each adjoining dummy device are connected to input/output pads. During testing the input/output pads are used to bias the nodes of a selected test device as well as the distal node(s) of any adjoining dummy device. By biasing the distal node(s) of an adjoining dummy device, random accumulation of potential thereon is avoided and current contributions from the adjoining dummy device(s) to a current measurement taken from the selected test device can be accurately determined.

Abstract: A method of forming an active contact-gate contact interconnect including forming a first gate contact to a first gate electrode in an active region in a substrate, forming a first active contact to another portion of the first active region. The first gate contact and the first active contact include an approximately equal surface area, and forming an interconnect between the first active contact and the first gate contact. The interconnect includes a first metal wire in a first metal layer electrically connecting the first active contact to the first gate contact. The method may also include forming a second metal wire in the first metal layer configured to electrically connect a third metal wire in a second metal layer to an external contact to a second active region in the substrate, the external contact including the approximately equal surface area.

Abstract: The disclosure provides integrated circuit (IC) structure including: a substrate; a shallow trench isolation (STI) positioned between the first and second regions of the substrate; a first transistor with a channel region is positioned on the first region of the substrate, and spacer positioned on the first region of the substrate and the STI; and a gate metal positioned on the spacer. The gate metal includes a gate contact region positioned over the first source/drain region of the substrate, and surrounding the channel region. Across-couple region extends laterally from the gate contact region to the source/drain region of a second transistor formed on the second region of the substrate.

Abstract: A method of forming an active contact-gate contact interconnect including forming a first gate contact to a first gate electrode in an active region in a substrate, forming a first active contact to another portion of the first active region. The first gate contact and the first active contact include an approximately equal surface area, and forming an interconnect between the first active contact and the first gate contact. The interconnect includes a first metal wire in a first metal layer electrically connecting the first active contact to the first gate contact. The method may also include forming a second metal wire in the first metal layer configured to electrically connect a third metal wire in a second metal layer to an external contact to a second active region in the substrate, the external contact including the approximately equal surface area.

Abstract: Methods of forming a VFET SRAM or logic device having a sub-fin level metal routing layer connected to a gate of one transistor pair and to the bottom S/D of another transistor pair and resulting device are provided. Embodiments include pairs of fins formed on a substrate; a bottom S/D layer patterned on the substrate around the fins; conformal liner layers formed over the substrate; a ILD formed over a liner layer; a metal routing layer formed between the pairs of fins on the liner layer between the first pair and on the bottom S/D layer between at least the second pair, an upper surface formed below the active fin portion; a GAA formed on the dielectric spacer around each fin of the first pair; and a bottom S/D contact xc or a dedicated xc formed on the metal routing layer adjacent to the GAA or through the GAA, respectively.

Abstract: Methods of forming a VFET SRAM or logic device having a sub-fin level metal routing layer connected to a gate of one transistor pair and to the bottom S/D of another transistor pair and resulting device are provided. Embodiments include pairs of fins formed on a substrate; a bottom S/D layer patterned on the substrate around the fins; conformal liner layers formed over the substrate; a ILD formed over a liner layer; a metal routing layer formed between the pairs of fins on the liner layer between the first pair and on the bottom S/D layer between at least the second pair, an upper surface formed below the active fin portion; a GAA formed on the dielectric spacer around each fin of the first pair; and a bottom S/D contact xc or a dedicated xc formed on the metal routing layer adjacent to the GAA or through the GAA, respectively.

Abstract: Methods form structures to include a first pair of complementary transistors (having first and second transistors) and a second pair of complementary transistors (having third and fourth transistors). An active area of the first transistor contacts an active area of the second transistor along a first common edge that is straight, and an active area of the third transistor contacts an active area of the fourth transistor along a second common edge that is straight and parallel to the first common edge. The active area of the second transistor has a third edge, opposite the first common edge, that has a non-linear shape, and the active area of the third transistor has a fourth edge, opposite the second common edge, that has the same non-linear shape. The non-linear shape of the third edge faces and is inverted relative to the non-linear shape of the fourth edge.

Abstract: Methods of forming a VFET SRAM or logic device having a sub-fin level metal routing layer connected to a gate of one transistor pair and to the bottom S/D of another transistor pair and resulting device are provided. Embodiments include pairs of fins formed on a substrate; a bottom S/D layer patterned on the substrate around the fins; conformal liner layers formed over the substrate; a ILD formed over a liner layer; a metal routing layer formed between the pairs of fins on the liner layer between the first pair and on the bottom S/D layer between at least the second pair, an upper surface formed below the active fin portion; a GAA formed on the dielectric spacer around each fin of the first pair; and a bottom S/D contact xc or a dedicated xc formed on the metal routing layer adjacent to the GAA or through the GAA, respectively.

Abstract: Methods form structures to include a first pair of complementary transistors (having first and second transistors) and a second pair of complementary transistors (having third and fourth transistors). An active area of the first transistor contacts an active area of the second transistor along a first common edge that is straight, and an active area of the third transistor contacts an active area of the fourth transistor along a second common edge that is straight and parallel to the first common edge. The active area of the second transistor has a third edge, opposite the first common edge, that has a non-linear shape, and the active area of the third transistor has a fourth edge, opposite the second common edge, that has the same non-linear shape. The non-linear shape of the third edge faces and is inverted relative to the non-linear shape of the fourth edge.

Abstract: Dual port static random access memory (SRAM) bitcell structures with improve symmetry in access transistors physical placement are provided. The bitcell structures may include, for example, two pairs of parallel pull-down transistors. The bitcell structures may also include pass-gate transistors PGLA and PGRA forming a first port, and pass-gate transistors PGLB and PGRB forming a second port. The pass-gate transistors PGLA and PGLB may be adjacent one another and a first side of the bitcell structure, and pass-gate transistors PGRA and PGRB may be adjacent one another and a second side of the bitcell structure. Each of the pass-gate transistors PGLA and PGLB may be connected with one of the pull-down transistors of one of the pairs of parallel pull-down transistors. Similarly, each of the pass-gate transistors PGRA and PGRB may be connected with one of the pull-down transistors of the other pair of parallel pull-down transistors.

Abstract: A method includes designating a cell mismatch parameter of a memory cell including a plurality of transistors and an initial value of a transistor mismatch parameter for each of the plurality of transistors. A critical current sensitivity parameter is determined for each of the plurality of transistors based on the transistor mismatch parameters in a computing apparatus. The cell mismatch parameter is distributed across the plurality of transistors in the computing apparatus to update the individual transistor mismatch parameters for each of the plurality of transistors based on the critical current sensitivity parameters and the cell mismatch parameter. The memory cell is simulated based on the individual transistor mismatch parameters to generate a simulation result.

Abstract: Dual port static random access memory (SRAM) bitcell structures with improve symmetry in access transistors physical placement are provided. The bitcell structures may include, for example, two pairs of parallel pull-down transistors. The bitcell structures may also include pass-gate transistors PGLA and PGRA forming a first port, and pass-gate transistors PGLB and PGRB forming a second port. The pass-gate transistors PGLA and PGLB may be adjacent one another and a first side of the bitcell structure, and pass-gate transistors PGRA and PGRB may be adjacent one another and a second side of the bitcell structure. Each of the pass-gate transistors PGLA and PGLB may be connected with one of the pull-down transistors of one of the pairs of parallel pull-down transistors. Similarly, each of the pass-gate transistors PGRA and PGRB may be connected with one of the pull-down transistors of the other pair of parallel pull-down transistors.