A semiconductor device may include a first active fin, a plurality of second active fins, a first source/drain layer structure, and a second source/drain layer structure. The first active fin may be on a first region of a substrate. The second active fins may be on a second region of the substrate. The first and second gate structures may be on the first and second active fins, respectively. The first source/drain layer structure may be on a portion of the first active fin that is adjacent to the first gate structure. The second source/drain layer structure may commonly contact upper surfaces of the second active fins adjacent to the second gate structure. A top surface of the second source/drain layer structure may be further from the surface of the substrate than a top surface of the first source/drain layer structure is to the surface of the substrate.

In a self-aligned fin cut process for fabricating integrated circuits, a sacrificial gate or an epitaxially-formed source/drain region is used as an etch mask in conjunction with a fin cut etch step to remove unwanted portions of the fins. The process eliminates use of a lithographically-defined etch mask to cut the fins, which enables precise and accurate alignment of the fin cut.

A semiconductor device includes a first Static Random Access Memory (SRAM) array including a first SRAM cell and a second SRAM array including a second SRAM cell. The first SRAM cell includes a first pull-down (PD) device including a single fin N-type FinFET. The single fin N-type FinFET includes a first gate dielectric having a first thickness. The second SRAM cell includes a second PD device including a multiple fin N-type FinFET. The multiple fin N-type FinFET includes a second gate dielectric having a second thickness. The first thickness is greater than the second thickness.

A multi-stack semiconductor device includes: a plurality of lower transistor structures arranged on a lower stack and including a plurality of lower fin structures surrounded by a plurality of lower gate structures, respectively; a plurality of upper transistor structures arranged on an upper stack and including a plurality of upper fin structures surrounded by a plurality of upper gate structures, respectively; and at least one of a lower diffusion break structure on the lower stack and a upper diffusion break structure on the upper stack, wherein the lower diffusion break structure is formed between two adjacent lower gate structures, and isolates two lower transistor structures respectively including the two adjacent lower gate structures from each other, and the upper diffusion break structure is formed between two adjacent upper gate structures, and isolates two upper transistor structures respectively including the two adjacent upper gate structures from each other.

Embodiments of the present disclosure relates to an integrated circuit including an array of memory cells connected to word lines and bit lines located on opposite sides of the memory cells. The memory cell may include gate all around transistors. A memory circuit according to the present disclosure also includes edge cells having word line tap structures configured to connect front side word lines with back side word lines. Some embodiments of the present disclosure provide an IC chip having memory cells with power rail on the front side and logic cells with power rail on the back side.

The static random access memory (SRAM) cell of the present disclosure includes a first pull-down device, a second pull-down device, a first pass-gate device, and a second pass-gate device in a first p-well on a substrate; a third pull-down device, a fourth pull-down device, a third pass-gate device, and a fourth pass-gate device in a second p-well on the substrate; a first pull-up device and a second pull-up device in an n-well between the first p-well and the second p-well; and a first landing pad between the second pull-down device and the first pull-up device. The first landing pad is electrically coupled to a gate structure of the second pass-gate device by way of a first gate via.

A semiconductor device includes a first region, a second region, a third region, and a fourth region. The first region includes a first portion of an N-well and a plurality of P-type transistors formed over the first portion of the N-well. The first region extends in a first direction. The second region includes a first portion of a P-well and a plurality of N-type transistors formed over the first portion of the P-well. The second region extends in the first direction. The third region includes a second portion of the P-well. The fourth region includes a second portion of the N-well. The first region and the second region are disposed between the third region and the fourth region.

Semiconductor devices and methods are provided. A semiconductor device of the present disclosure includes a bias source, a memory cell array including a first region adjacent to the bias source and a second region away from the bias source, and a conductive line electrically coupled to the bias source, a first memory cell in the first region and a second memory cell in the second region. The first memory cell is characterized by a first alpha ratio and the second memory cell is characterized by a second alpha ratio smaller than the first alpha ratio.

A semiconductor device structure is provided. The semiconductor device structure includes a first device formed over a substrate, wherein the first device includes a first fin structure and a first S/D structure formed over the first fin structure. The semiconductor device structure includes a second device formed over or below the first device, and the second device includes a plurality of second nanostructures stacked in a vertical direction. The semiconductor device structure also includes a second S/D structure formed over the second nanostructures, and the second S/D structure is directly above or below the first S/D structure.

A semiconductor memory device includes an active pattern on a substrate, the active pattern including a source/drain pattern in an upper portion thereof, a gate electrode on the active pattern and extended in a first direction, the gate electrode and the source/drain pattern adjacent to each other in a second direction that crosses the first direction, and a shared contact coupled to the source/drain pattern and the gate electrode to electrically connect the source/drain pattern and the gate electrode. The shared contact includes active and gate contacts, which are electrically connected to the source/drain pattern and the gate electrode, respectively. The gate contact includes a body portion coupled to the gate electrode and a protruding portion, which protrudes from the body portion in the second direction and extends into and buried in the active contact.