A method includes forming a fin structure including a first channel layer, a sacrificial layer, and a second channel layer over a substrate; forming a dummy gate structure across the fin structure; recessing the fin structure; epitaxially growing first source/drain epitaxial structures on opposite sides of the first channel layer; forming first dielectric layers to cover the first source/drain epitaxial structures, respectively; epitaxially growing second source/drain epitaxial structures on opposite sides of the second channel layer; removing the dummy gate structure and the sacrificial layer to form a gate trench between the first source/drain epitaxial structures and between the second source/drain epitaxial structures; and forming a metal gate structure in the gate trench. The second source/drain epitaxial structures are over the first dielectric layers, respectively.

An IC device includes a first and second stacked transistor structures including respective first and second and third and fourth transistors in a semiconductor substrate, first and second bit lines and a word line on one of a front or back side of the semiconductor substrate, and a power supply line on the other of the front or back side. The first transistor includes a source/drain (S/D) terminal electrically connected to the first bit line, a S/D terminal electrically connected to a S/D terminal of the second transistor, and a gate electrically connected to the word line, the third transistor includes a S/D terminal electrically connected to the second bit line, a S/D terminal electrically connected to a S/D terminal of the fourth transistor, and a gate electrically connected to the word line, and the second and fourth transistors include S/D terminals electrically connected to the power supply line.

A semiconductor structure is provided that includes a first stacked FET cell including a second FET stacked over a first FET, and a second stacked FET cell located adjacent to the first stacked FET cell and including a fourth FET stacked over a third FET. The structure further includes a first backside source/drain contact structure located beneath the first stacked FET cell and contacting a source/drain region of the first FET, a second backside source/drain contact structure located beneath the second stacked FET cell and contacting a source/drain region of the third FET, and an angled cut region laterally separating the first backside source/drain contact structure from the second backside source/drain contact structure.

Various embodiments of the present disclosure are directed towards a method for forming an integrated chip. The method includes forming an epitaxial structure having a first doping type over a first portion of a semiconductor substrate. A second portion of the semiconductor substrate is formed over the epitaxial structure and the first portion of the semiconductor substrate. A first doped region having the first doping type is formed in the second portion of the semiconductor substrate and directly over the epitaxial structure. A second doped region having a second doping type opposite the first doping type is formed in the second portion of the semiconductor substrate, where the second doped region is formed on a side of the epitaxial structure. A plurality of fins of the semiconductor substrate are formed by selectively removing portions of the second portion of the semiconductor substrate.

Various implementations described herein are directed to a device having a skew cell architecture with multiple diffusion regions including P-type diffusion regions disposed between N-type diffusion regions. The device may have power rails including a voltage supply rail disposed between ground rails. The device may have poly-gate rails disposed between the ground rails. The poly-gate rails may be cut to provide an open space between at least one N-type diffusion region and at least one P-type diffusion region.

A semiconductor device and a method for manufacturing the same. The semiconductor device comprises an n-channel GAA transistor and a p-channel GAA transistor, which are spaced apart. Each of the n-channel GAA transistor and the p-channel GAA transistor comprises a source, a drain, and at least one nanostructure layer located between the source and the drain. The p-channel GAA transistor further comprises a gate stack structure and a gate sidewall. In the p-channel GAA transistor, the at least one nanostructure layer comprises a channel portion that is covered by the gate stack structure and a connecting portion that is covered by the gate sidewall, and germanium content in the channel portion is greater than germanium content in the connecting portion and is greater than germanium content in the at least one nanostructure layer of the n-channel GAA transistor.

A method of generating a layout design of an integrated circuit includes forming an active zone and partitioning the active zone into a center portion between a first side portion and a second side portion. The method also includes forming a plurality of gate-strips and forming a routing line. The plurality of gate-strips includes a first group of gate-strips intersecting the active zone over first channel regions in the center portion, a second group of gate-strips intersecting the active zone over second channel regions in the center portion, a third group of gate-strips intersecting the active zone over third channel regions in the first side portion, and a fourth group of gate-strips intersecting the active zone over fourth channel regions in the second side portion.

A flip-flop includes a first input circuit, a first NOR logic gate, a stacked gate circuit, a first NAND logic gate and an output circuit. The first input circuit generates a first signal responsive to at least a first data signal, a first or a second clock signal. The first NOR logic gate is coupled between a first and a second node, and generates a second signal responsive to the first signal and a first reset signal. The stacked gate circuit is coupled between the first and a third node, and generates a third signal responsive to the first signal. The first NAND logic gate is coupled between the third and a fourth node, and generates a fourth signal responsive to the third signal and a second reset signal. The output circuit is coupled to the fourth node, and generates a first output signal responsive to the fourth signal.

Embodiments of the disclosure are in the field of advanced integrated circuit structure fabrication and, in particular, 10 nanometer node and smaller integrated circuit structure fabrication and the resulting structures. In an example, an integrated circuit structure includes a first silicon fin having a longest dimension along a first direction. A second silicon fin having a longest dimension is along the first direction. An insulator material is between the first silicon fin and the second silicon fin. A gate line is over the first silicon fin and over the second silicon fin along a second direction, the second direction orthogonal to the first direction, the gate line having a first side and a second side, wherein the gate line has a discontinuity over the insulator material, the discontinuity filled by a dielectric plug.

Embodiments of the disclosure are in the field of advanced integrated circuit structure fabrication and, in particular, 10 nanometer node and smaller integrated circuit structure fabrication and the resulting structures. In an example, an integrated circuit structure includes a fin. An isolation structure surrounds a lower fin portion, the isolation structure comprising an insulating material having a top surface, and a semiconductor material on a portion of the top surface of the insulating material, wherein the semiconductor material is separated from the fin. A gate dielectric layer is over the top of an upper fin portion and laterally adjacent the sidewalls of the upper fin portion, the gate dielectric layer further on the semiconductor material on the portion of the top surface of the insulating material. A gate electrode is over the gate dielectric layer.