A SRAM cell structure includes a plurality of transistors, a set of contacts, a word-line, a bit-line, a VDD contacting line and a VSS contacting line. The plurality of transistors include n transistors, wherein n is a positive integral less than 6. The set of contacts are coupled to the plurality of transistors. The word-line is electrically coupled to the plurality of transistors. The bit-line and a bit line bar are electrically coupled to the plurality of transistors. The VDD contacting line is electrically coupled to the plurality of transistors. The VSS contacting line is electrically coupled to the plurality of transistors. Wherein as a minimum feature size of the SRAM cell structure gradually decreases from 28 nm, an area size of the SRAM cell in terms of square of the minimum feature size (λ) is the same or substantially the same.

A static random-access memory (SRAM) device including a three-dimensional structured (3DS) field-effect transistor (FET) having a minimized planar area and a simple wiring connection structure includes a semiconductor substrate, a first fin active region extending on the semiconductor substrate in a first direction, a second fin active region extending on the semiconductor substrate in the first direction and apart from the first fin active region in a second direction perpendicular to the first direction, and four gates extending in the second direction and intersecting part of the first fin active region or the second fin active region. Each of the first fin active region and the second fin active region includes a first region in which only a lower layer is arranged and a second region in which an upper layer is arranged on the lower layer.

A 3D semiconductor device with a built-in-test-circuit (BIST), the device comprising: a first single-crystal substrate with a plurality of logic circuits disposed therein, wherein said first single-crystal substrate comprises a device area, wherein said plurality of logic circuits comprise at least a first interconnected array of processor logic, wherein said plurality of logic circuits comprise at least a second interconnected set of circuits comprising a first logic circuit, a second logic circuit, and a third logic circuit, wherein said second interconnected set of logic circuits further comprise switching circuits that support replacing said first logic circuit and/or said second logic circuit with said third logic circuit; and said built-in-test-circuit (BIST), wherein said first logic circuit is testable by said built-in-test-circuit (BIST), and wherein said second logic circuit is testable by said built-in-test-circuit (BIST).

A 3D semiconductor device with a built-in-test-circuit (BIST), the device comprising: a first single-crystal substrate with a plurality of logic circuits disposed therein, wherein said first single-crystal substrate comprises a device area, wherein said plurality of logic circuits comprise at least a first interconnected array of processor logic, wherein said plurality of logic circuits comprise at least a second interconnected set of circuits comprising a first logic circuit, a second logic circuit, and a third logic circuit, wherein said second interconnected set of logic circuits further comprise switching circuits that support replacing said first logic circuit and/or said second logic circuit with said third logic circuit; and said built-in-test-circuit (BIST), wherein said first logic circuit is testable by said built-in-test-circuit (BIST), and wherein said second logic circuit is testable by said built-in-test-circuit (BIST).

A memory circuit includes a first word line, a first and second bit line, a first and second inverter, a P-type pass gate transistor and a pre-charge circuit. The first word line extends in a first direction. The first and second bit line extend in a second direction. The first inverter has a first storage node coupled to the second inverter. The second inverter has a second storage node coupled to the first inverter, and is not coupled to the second bit line. The P-type pass gate transistor is coupled between the first storage node and the first bit line. The pre-charge circuit is coupled to the first or second bit line, and is configured to charge the first or second bit line to a pre-charge voltage responsive to a first signal. The pre-charge voltage is between a voltage of a first logical level and a second logical level.

A memory device comprises an interconnect comprises a spin orbit coupling (SOC) material. A free magnetic layer is on the interconnect, a barrier material is over the free magnetic layer and a fixed magnetic layer is over the barrier material, wherein the free magnetic layer comprises an antiferromagnet. In another embodiment, memory device comprises a spin orbit coupling (SOC) interconnect and an antiferromagnet (AFM) free magnetic layer is on the interconnect. A ferromagnetic magnetic tunnel junction (MTJ) device is on the AFM free magnetic layer, wherein the ferromagnetic MTJ comprises a free magnet layer, a fixed magnet layer, and a barrier material between the free magnet layer and the fixed magnet layer.

A method for forming ultra-high density integrated circuitry, such as for a 6T SRAM, for example, is provided. The method involves applying double patterning litho-etch litho-etch (LELE) and using a spacer process to shrink the critical dimension of features. To improve process margins, the method implements a double-patterning technique by modifying the layout and splitting cross-coupling straps into two colors (e.g., each color corresponds to a mask-etch process). In addition, a spacer process is implemented to shrink feature size and increase the metal-to-metal spacing between the two cross-coupling straps, in order to improve process margin and electrical performance. This is achieved by depositing a spacer layer over an opening in a hardmask, followed by spacer etch back. The opening is thus shrunk by the amount of spacer thickness. The strap-to-strap spacing may then be increased by twice the amount of spacer thickness.

A memory device includes active regions and gate structures, each of the gate structures is electrically coupled to a first portion of a corresponding active region of the active regions. The memory device includes contact-to-transistor-component structures (MD structures), each of the MD structures is over a second portion of a corresponding active region, and a first MD structure is between adjacent gate structures. The memory device includes via-to-gate/MD (VGD) structures, each of the VGD structures is over to a corresponding gate electrode and MD structure. The memory device includes conductive segments, each of the conductive segments is over and electrically coupled to a corresponding VGD structure. The memory device includes buried contact-to-transistor-component structures (BVD) structures, each of the BVD structures is under a third portion of a corresponding active region. The memory device includes buried conductive segments, each of the buried conductive segments is under a corresponding BVD structure.

A memory cell array includes a first and second memory cell, a first and second word line and a first bit line. The first memory cell is in a first row in a first direction. The second memory cell is in a second row in the first direction, and is separated from the first memory cell in a second direction. The first word line extends in the first direction and is coupled to the first memory cell. The second word line extends in the first direction and is coupled to the second memory cell. The first bit line extends in the second direction and is coupled to the first and second memory cell. The first memory cell corresponds to a five transistor memory cell. The first memory cell includes a first active region having a first length, and a second active region having a second length.

A product-sum calculation with high power efficiency is performed while maintaining a small area of a memory cell. A semiconductor device includes a memory cell array in which a plurality of memory cells is arranged in a matrix. Then, each memory cell of the plurality of memory cells includes a flip-flop circuit including two inverter circuits in each of which a load field effect transistor and a drive field effect transistor are connected in series, input portions and output portions of the two inverter circuits being cross-joined to each other, two transfer field effect transistors each having a gate electrode connected to a word line, and a pair of first and second main electrode regions, the first main electrode regions being respectively connected to the output portions of the two inverter circuits, and two resistance elements of which one end sides are respectively connected to the second main electrode regions of the two transfer field effect transistors and other end sides are respectively connected to a bit line and a bit line bar.