A semiconductor device includes a substrate, a first semiconductor fin, a second semiconductor fin, an n-type epitaxy structure, a p-type epitaxy structure, and a plurality of dielectric fin sidewall structures. The first semiconductor fin is disposed on the substrate. The second semiconductor fin is disposed on the substrate and adjacent to the first semiconductor fin. The n-type epitaxy structure is disposed on the first semiconductor fin. The p-type epitaxy structure is disposed on the second semiconductor fin and separated from the n-type epitaxy structure. The dielectric fin sidewall structures are disposed on opposite sides of at least one of the n-type epitaxy structure and the p-type epitaxy structure.

A layout pattern of a static random access memory includes a pull-up device, a first pull-down device, a second pull-up device, a second pull-down device, a first pass gate device, a second pass gate device, a third pass gate device and a fourth pass gate device disposed on a substrate. A plurality of fin structures is disposed on the substrate, the fin structures including at least one first fin structure and at least one second fin structure. A step-shaped structure is disposed on the substrate, including a first part, a second part and a bridge part. A first extending contact feature crosses over the at least one first fin structure and the at least one second fin structure.

A layout for a 6T SRAM cell array is disclosed. The layout doubles the number of bits per bit cell in the array by implementing dual pairs of bitlines spanning bit cell columns in the array. Alternating connections (e.g., alternating vias) may be provided for wordline access to the bitlines in the layout. Alternating the connections may reduce RC delay in the layout.

Devices and methods of fabricating integrated circuit devices with reduced cell height are provided. One method includes, for instance: obtaining an intermediate semiconductor device having a substrate including a logic area and an SRAM area, a fin material layer, and a hardmask layer; depositing a mandrel over the logic area; depositing a sacrificial spacer layer; etching the sacrificial spacer layer to define a sacrificial set of vertical spacers; etching the hardmask layer; leaving a set of vertical hardmask spacers; depositing a first spacer layer; etching the first spacer layer to define a first set of vertical spacers over the logic area; depositing an SOH layer; etching an opening in the SOH layer over the SRAM area; depositing a second spacer layer; and etching the second spacer layer to define a second set of spacers over the SRAM area.

Fabrication method for a semiconductor memory device and structure are provided, which includes: providing at least two mask layers over a pair of fin structures extended above a substrate, wherein a first mask layer of the at least two mask layers is orthogonal to a second mask layer of the at least two mask layers; and patterning the pair of fin structures to define a pass-gate transistor, wherein the first mask layer facilitates removing of a portion of a first fin structure of the pair of fin structures to define a first pass-gate fin portion of the pass-gate transistor, and the second mask layer protects a second fin structure of the pair of fin structures to define a second pass-gate fin portion of the pass-gate transistor.

At least one method, apparatus and system disclosed involves a memory device having a memory cell comprising NMOS only transistors. An SRAM bit cell comprises a first pass gate (PG) NMOS transistor coupled to a first bit line signal and a word line signal; a second PG NMOS transistor coupled to a second bit line signal and the word line signal; a first pull down (PD) NMOS transistor operatively coupled to the first PG NMOS transistor; a second PD NMOS transistor operatively coupled to the second PG NMOS transistor; a first pull up (PU) NMOS transistor operatively coupled to the first PD NMOS transistor; and a second PU NMOS transistor operatively coupled to the second PD NMOS transistor. Each of the back gates of the first and second PU NMOS transistors are coupled to a predetermined voltage signal for biasing the first and second PU NMOS transistors.

The present disclosure, in some embodiments, relates to a method of performing an etch process. The method is performed by forming a first plurality of openings defined by first sidewalls of a mask disposed over a substrate. A cut layer is between two of the first plurality of openings. A spacer is formed onto the first sidewalls of the mask and a second plurality of openings are formed. The second plurality of openings are defined by second sidewalls of the mask and are separated by the spacer. The substrate is etched according to the mask and the spacer.

A semiconductor memory device and a method for manufacturing the same. The semiconductor memory device may include a substrate, a first lower wire pattern and a first upper wire pattern stacked on the substrate, and spaced apart from each other; a second lower wire pattern and a second upper wire pattern stacked on the substrate, spaced apart from each other, and spaced apart from the first lower and upper wire patterns; a first gate line surrounding the first lower wire pattern and the first upper wire pattern; a second gate line surrounding the second lower wire pattern and the second upper wire pattern and spaced apart from the first gate line; a first lower source/drain area; a first upper source/drain area; and a first overlapping contact that electrically connects the first lower source/drain area, the first upper source/drain area and the second gate line to each other.

A method for fabricating a static random access memory (SRAM) includes the steps of: forming a gate structure on a substrate; forming an epitaxial layer adjacent to the gate structure; forming a first interlayer dielectric (ILD) layer around the gate structure; transforming the gate structure into a metal gate; forming a contact hole exposing the epitaxial layer, forming a barrier layer in the contact hole, forming a metal layer on the barrier layer, and then planarizing the metal layer and the barrier layer to form a contact plug. Preferably, a bottom portion of the barrier layer includes a titanium rich portion and a top portion of the barrier layer includes a nitrogen rich portion.

A bistable circuit includes a pair of inverter circuits each including a first FET being connected between a power supply line and an intermediate node and having a gate coupled to an input node and a first conductivity type channel, a second FET being connected between the intermediate node and an output node and having a gate coupled to the input node and the first conductivity type channel, a third FET being connected between the intermediate node and a bias node, a fourth FET being connected between the output node and a control line and having a gate coupled to a word line and a second conductivity type channel, wherein the pair of inverter circuits are connected in a loop shape, and gates of the third FETs of the pair of inverter circuits are coupled to one of the input and output nodes of the pair of inverter circuits.