A butted contact structure is provided. In one embodiment, a structure includes a first transistor on a substrate, the first transistor comprising a first source or drain region, a first gate, and a first gate spacer being disposed between the first gate and the first source or drain region. The structure includes a second transistor on the substrate, the second transistor comprising a second source or drain region, a second gate, and a second gate spacer being disposed between the second gate and the second source or drain region. The structure includes a butted contact disposed above and extending from the first source or drain region to at least one of the first or second gate, a portion of the first gate spacer extending a distance into the butted contact to separate a first bottom surface of the butted contact from a second bottom surface of the butted contact.

A memory device includes an array of memory cells and a plurality of bit-lines with each bit-line connected to a respective set of memory cells of the array of memory cells. The memory device includes a memory subsystem having first and second memory circuits. Each first memory circuit can be disposed laterally adjacent to a second memory circuit. Each first memory circuit includes a first bit-line connection and each second memory circuit including a second bit-line connection, the first and second bit-line connections can connect to respective bit-lines. Each first bit-line connection is disposed on a first bit-line connection line of the memory subsystem and each second bit-line connection is disposed on a second bit-line connection line of the memory subsystem, and the second bit-line connection line can be offset from the first bit-line connection line by a predetermined distance that is greater than zero.

Integrated circuit (“IC”) layouts are disclosed for improving performance of memory arrays, such as static random access memory (“SRAM”). An exemplary IC device includes an SRAM cell and an interconnect structure electrically coupled to the SRAM cell. The interconnect structure includes a first metal layer electrically coupled to the SRAM cell that includes a bit line, a first voltage line having a first voltage, a word line landing pad, and a second voltage line having a second voltage that is different than the first voltage. The first voltage line is adjacent the bit line. The word line landing pad is adjacent the first voltage line. The second voltage line is adjacent the word line landing pad. A second metal layer is disposed over the first metal layer. The second metal layer includes a word line that is electrically coupled to the word line landing pad.

New CMOS harvesting circuits are proposed that improve 2-port/multiport Register File Array circuit speed and substantially lower the energy cost of moving data along local and global bitpaths when engaging harvested data to self-limit energy dissipation. The uncertainty in BL signal development due to statistical variations in cell read current is eliminated by self-disabling action in the selected cell when the electric potential of harvested data matches the BL voltage from signal development while demanding fewer peripheral circuit transistors per column than conventional sensing schemes. Proposed bit path circuits engage harvested charge to provide immunity to disturb current noise during concurrent Read and Write access along a wL-eliminating the performance, area and energy overheads of BL keeper circuits typically required in conventional Register File arrays. Proposed circuits improve the reliability of Read performance-limiting bitcell devices from voltage accelerated aging mechanisms by lowering of vertical and lateral electric fields across these cell transistors when holding harvested charge during most of active and standby periods. Register File bitcell transistor design trade-off constraints between array leakage in active mode and read current are considerably relaxed when engaging harvested charge enabling much higher read currents for any given total array leakage. Area overheads of proposed circuits are expected to be marginally lower based on device widths of replacements to conventional peripheral circuits and can be further minimized by sharing of devices and their connections between bit slices of the array peripheral circuits. Moreover, proposed circuits do not require any changes to the CMOS platform, to the bitcell or to the array architecture with much of the flow for design, verification and test of 2-Port/multiport RF Memory arrays expected to remain unchanged—minimizing risk and allowing integration of proposed circuits into existing products with minimal disruption to schedule and cost.

Header circuitry for a memory device includes multiple backside power rails that form distinct voltage sources for a plurality of switching devices in the header circuitry. The header circuitry includes at least one region of a first conductivity type. A first section in the first region includes one backside power rail (BPR) that forms a first voltage source that provides a first voltage. A second section in the same first region includes another BPR that forms a second voltage source that provides a second voltage that is different from the first voltage.

Disclosed herein are related to a memory cell including magnetic tunneling junction (MTJ) devices. In one aspect, the memory cell includes a first layer including a first transistor and a second transistor. In one aspect, the first transistor and the second transistor are connected to each other in a cross-coupled configuration. A first drain structure of the first transistor may be electrically coupled to a first gate structure of the second transistor, and a second drain structure of the second transistor may be electrically coupled to a second gate structure of the first transistor. In one aspect, the memory cell includes a second layer including a first MTJ device electrically coupled to the first drain structure of the first transistor and a second MTJ device electrically coupled to the second drain structure of the second transistor. In one aspect, the second layer is above the first layer.

In the present disclosure, it has been appreciated that memory structures, such as static random access memory (SRAM) structures, have feature densities that are extremely high. While this is beneficial in allowing the memory structures to store large amounts of data in a small chip footprint, it is potentially detrimental in that it makes the memory structures more susceptible to leakage current than the other areas of the chip. Accordingly, the present disclosure provides pseudo memory structures which are similar in terms of layout spacing to actual memory structures. However, rather than being used as actual memory structures that store data during operation, these pseudo memory structures are used to characterize leakage current in the design of the IC and/or to characterize the fabrication process used to manufacture the IC.

A Static Radom Access Memory (SRAM) cell includes a pass-gate transistor and a pull-down transistor. The pass-gate transistor includes a first active region and a first gate structure engaging the first active region. The pull-down transistor includes a second active region and a second gate structure engaging the second active region. The SRAM cell further includes a first isolation feature abutting the first gate structure and a second isolation feature abutting the second gate structure. The first isolation feature is spaced from the first active region of the pass-gate transistor for a first distance. The second isolation feature is spaced from the second active region of the pull-down transistor for a second distance that is larger than the first distance.

Embodiments of bonded unified semiconductor chips and fabrication and operation methods thereof are disclosed. In an example, a method for forming a unified semiconductor chip is disclosed. A first semiconductor structure is formed. The first semiconductor structure includes one or more processors, an array of embedded DRAM cells, and a first bonding layer including a plurality of first bonding contacts. A second semiconductor structure is formed. The second semiconductor structure includes an array of NAND memory cells and a second bonding layer including a plurality of second bonding contacts. The first semiconductor structure and the second semiconductor structure are bonded in a face-to-face manner, such that the first bonding contacts are in contact with the second bonding contacts at a bonding interface.

A semiconductor structure includes an array of two-port (TP) SRAM cells, each of which includes a write port and a read port. The write port includes two write pass gate (W_PG) transistors, two write pull-down (W_PD) transistors, and two write pull-up (W_PU) transistors. The array of TP SRAM cells includes first and second TP SRAM cells whose write ports abuts each other. Two W_PG transistors of the first and second TP SRAM cells share a common gate electrode. Source/drain electrodes of two W_PD transistors of the first and second TP SRAM cells share a common contact. The first TP SRAM cell includes a Vss conductor connected to the common contact. The second TP SRAM cell includes a write word line (W_WL) landing pad connected to the common gate electrode. The Vss conductor and the W_WL landing pad are located at a first metal layer.