Abstract: Integrated circuit structures having fin isolation regions recessed for gate contact are described. In an example, an integrated circuit structure includes a vertical stack of horizontal nanowires over a first sub-fin. A gate structure is over the vertical stack of horizontal nanowires and on the first sub-fin. A dielectric structure is laterally spaced apart from the gate structure. The dielectric structure is not over a channel structure but is on a second sub-fin. A dielectric gate cut plug is between the gate structure and the dielectric structure. A recess is in the dielectric structure and in the dielectric gate cut plug. A conductive structure is in the recess, the conductive structure in lateral contact with a gate electrode of the gate structure.

Abstract: Stacked static random-access memory (SRAM) circuits have doubled word length for a given SRAM cell area. An integrated circuit (IC) die includes stacked SRAM cells in vertically adjacent device layers with access transistors connected to a common wordline. The IC die with stacked SRAM cells having a common word line may be attached to a substrate and coupled to a power supply and, advantageously, to an active-cooling structure. SRAM cells may be formed in vertically adjacent layers of a substrate and electrically connected at their access transistor gate electrodes.

Abstract: Embodiments of the present disclosure include integrated circuit structures having differentiated channel sizing, and methods of fabricating integrated circuit structures having differentiated channel sizing. In an example, a structure includes a memory region having a first vertical stack of horizontal nanowires having a first number of nanowires. The integrated circuit structure also includes a logic region having a second vertical stack of horizontal nanowires spaced apart from the first vertical stack of horizontal nanowires. The second vertical stack of horizontal nanowires has a second number of nanowires less than the first number of nanowires.

Abstract: Embodiments described herein may be related to apparatuses, processes, systems, and techniques directed to electrical couplings between epitaxial structures and voltage sources within transistors in SRAM bit cells. Embodiments include direct electrical couplings between a backside contact metal (BMO) and a backside of an epitaxial structure to provide SRAM VCC voltage (SVCC) voltage, as well as electrical connection structures that electrically couple the BMO to a front side of an epitaxial structure to provide SVCC voltage. Other embodiments may be described and/or claimed.

Abstract: Embodiments described herein may be related to apparatuses, processes, systems, and techniques directed to electrical couplings between epitaxial structures and voltage sources within transistors in SRAM bit cells. Embodiments include direct electrical couplings between a backside contact metal (BM0) and a backside of an epitaxial structure, as well as electrical connection structures that electrically couple the BM0 to a front side of an epitaxial structure. Other embodiments may be described and/or claimed.

Abstract: Integrated circuit (IC) devices include transistors with gate, source and drain contact metallization, some of which are jumpered together by a metallization that is recessed below a height of other metallization that is not jumpered. The jumper metallization may provide a local interconnect between terminals of one transistor or adjacent transistors, for example between a gate of one transistor and a source/drain of another transistor. The jumper metallization may not induce the same pitch constraints faced by interconnect line metallization levels employed for more general interconnection. In some examples, a static random-access memory (SRAM) bit-cell includes a jumper metallization joining two transistors of the cell to reduce cell height for a given feature patterning capability.

Abstract: Integrated circuit (IC) static random-access memory (SRAM) bit-cell structures comprising pass-gate transistors having a different number of active channel regions than the number of active channel regions in pull-down transistors. A pass-gate transistor with fewer active channel regions than a pull-down transistor may reduce read instability of an SRAM bit-cell, and/or reduce overhead associated with read assist circuitry coupled to the bit-cell. In some examples, one or more pass-gate transistor channel regions are impurity doped or removed from either a top side or bottom side of the pass-gate transistors to depopulate the number of active channel regions relative to a pull-down transistor.

Abstract: Integrated circuit (IC) static random-access memory (SRAM) comprising pass-gate transistors and pull-down transistors having different threshold voltages (Vt). A pass-gate transistor with a higher Vt than the pull-down transistor, may reduce read instability of a bit-cell, and/or reduce overhead associated with read assist circuitry coupled to the bit-cell. In some examples, a different amount of a dipole dopant source material is deposited as part of the gate insulator for the pull-down transistor than for the pass-gate transistor, reducing the Vt of the pull-down transistor accordingly. In some examples, an N-dipole dopant source material is removed from the pass-gate transistor prior to a drive/activation anneal is performed. After drive/activation, the N-dipole dopant source material may be removed from the pull-down transistor and a same gate metal deposited over both the pass-gate and pull-down transistors.

Abstract: Integrated circuit (IC) static random-access memory (SRAM) comprising colinear pass-gate transistors and pull-down transistors having different nanoribbon widths. A narrower ribbon width within the pass-gate transistor, relative to the pull-down transistor, may reduce read instability of a bit-cell, and/or reduce overhead associated with read assist circuitry coupled to the bit-cell. In some examples, a transition between narrower and width ribbon widths is symmetrical about a centerline shared by ribbons of both the access and pull-down transistors. In some examples, the ribbon width transition is positioned within an impurity-doped semiconductor region shared by the access and pull-down transistors and may be located under a terminal contact metallization. In some examples, the impurity-doped semiconductor regions surrounding the ribbons of differing width also have differing widths.

Abstract: Gate-all-around integrated circuit structures having depopulated channel structures, and methods of fabricating gate-all-around integrated circuit structures having depopulated channel structures using a directed bottom-up approach, are described. For example, an integrated circuit structure includes a vertical arrangement of nanowires above a substrate. A gate stack is over and around the vertical arrangement of nanowires. A first epitaxial source or drain structure is at a first end of the vertical arrangement of nanowires. A second epitaxial source or drain structure is at a second end of the vertical arrangement of nanowires, the second end opposite the first end, wherein at least one of the first or second epitaxial source or drain structures is coupled to fewer than all nanowires of the vertical arrangement of nanowires.

Abstract: Some embodiments include apparatuses having non-volatile memory cells, each of the non-volatile memory cells to store more than one bit of information; data lines, at most one of the data lines electrically coupled to each of the non-volatile memory cells; a circuit including transistors coupled to the data lines, the transistors including gates coupled to each other; and an encoder including input nodes and output nodes, the input nodes to receive input information from the data lines through the transistors, and the output nodes to provide output information having a value based on a value of the input information.

Abstract: Systems and methods for precision writing of weight values to a memory capable of storing multiple levels in each cell are disclosed. Embodiments include logic to compare an electrical parameter read from a memory cell with a base reference and an interval reference, and stop writing once the electrical parameter is between the base reference and the base plus the interval reference. The interval may be determined using a greater number of levels than the number of stored levels, to prevent possible overlap of read values of the electrical parameter due to memory device variations.

Abstract: Some embodiments include apparatuses having non-volatile memory cells, each of the non-volatile memory cells to store more than one bit of information; data lines, at most one of the data lines electrically coupled to each of the non-volatile memory cells; a circuit including transistors coupled to the data lines, the transistors including gates coupled to each other; and an encoder including input nodes and output nodes, the input nodes to receive input information from the data lines through the transistors, and the output nodes to provide output information having a value based on a value of the input information.