A semiconductor device and methods of fabricating the same are disclosed. The method includes forming a fin structure on a substrate, forming a superlattice structure with first and second nanostructured layers on the fin structure, forming a polysilicon structure around the superlattice structure, forming a source/drain opening within the superlattice structure, forming a first conductivity type S/D region within a first portion of the S/D opening, forming an isolation layer on the first conductivity type S/D region and within a second portion of the S/D opening, forming a second conductivity type S/D region on the isolation layer and within a third portion the S/D opening, and replacing the polysilicon structure and the second nanostructured layers with a gate structure that surrounds the first nanostructured layers. Materials of the first and second nanostructured layers are different from each other and the second conductivity type is different from the first conductivity type.

The present description concerns an integrated circuit chip including a semiconductor substrate and a radiofrequency component arranged inside and on top of an active region of the semiconductor substrate. The semiconductor substrate includes an amorphous buried layer in contact, by its upper surface, with a lower surface of the active region of the semiconductor substrate.

Vertically superimposed lateral gate-all-around metal-oxide-semiconductor field-effect transistors are provided, a structure of a novel three-dimensional integrated circuit such as a CMOS logic circuit that is composed of the vertically superimposed lateral gate-all-around transistors, a random-access memory and the like, and a manufacturing method for the novel three-dimensional integrated circuit are provided. The manufacturing method for the vertically superimposed lateral gate-all-around transistors includes: first preparing a monolayer channel and a source/drain, then protected with a sacrificial layer; preparing an insulating isolation layer, preparing above repeated structures on the insulating isolation layer; preparing an insulating spacer layer between the source/drain and a gate of each of the layers, a gate oxide, a gate, and a source/drain electrode in a unified manner, and finally preparing a connecting wire connected to the outside. The novel three-dimensional integrated circuit can be implemented by connecting the lateral gate-all-around transistors by means of a wire.

Methods for forming a semiconductor structure and semiconductor structures are described. The method comprises patterning a substrate to form a first opening and a second opening, the substrate comprising an n transistor and a p transistor, the first opening over the n transistor and the second opening over the p transistor. The substrate may be pre-cleaned. A ruthenium silicide (RuSi) layer is selectively deposited on the p transistor. A titanium silicide (TiSi) layer is formed on the n transistor and the p transistor. An optional barrier layer may be formed on the titanium silicide (TiSi) layer. The method may be performed in a processing chamber without breaking vacuum.

A device includes first nanostructures over a substrate; second nanostructures over the substrate, wherein the first nanostructures are laterally separated from the second nanostructures by an isolation structure between the first nanostructures and the second nanostructures; a first gate structure around each first nanostructure and around each second nanostructure, wherein the first gate structure extends over the isolation structure; third nanostructures over the substrate; and a second gate structure around each third nanostructure, wherein the second gate structure is separated from the first gate structure by a dielectric wall.

A semiconductor device includes a first region and a second region disposed adjacent to each other and having a boundary therebetween. The first region includes a first active region, a second active region and a third active region extending in a first direction and having different widths measured along a second direction. The first region includes a first gate electrode, a second gate electrode and a third gate electrode extending in the second direction and disposed across the first active region, the second active region and the third active region respectively. From a top view, the first active region has a first edge and a second edge opposite to each other, the first edge of the first active region is aligned with an edge of the second active region, and the second edge of the first active region is aligned with an edge of the third active region.

A 3D semiconductor device including: a first level including a first single crystal layer and first transistors, which each include a single crystal channel; a first metal layer with an overlaying second metal layer; a second level including second transistors, overlaying the first level; a third level including third transistors, overlaying the second level; a fourth level including fourth transistors, overlaying the third level, where the second level includes first memory cells, where each of the first memory cells includes at least one of the second transistors, where the fourth level includes second memory cells, where each of the second memory cells includes at least one of the fourth transistors, where the first level includes memory control circuits, where second memory cells include at least four memory arrays, each of the four memory arrays are independently controlled, and at least one of the second transistors includes a metal gate.

A field-effect transistor includes a substrate, a channel on the substrate including a stem including silicon extending in a vertical direction from the substrate and a number of prongs including silicon extending in a horizontal direction from the stem and spaced apart from each other along the vertical direction, an interfacial layer surrounding the stem and the prongs of the channel, a dielectric layer on the interfacial layer and surrounding the stem and the prongs of the channel, and a metal gate on the dielectric layer and surrounding the stem and the prongs of the channel.

A semiconductor device includes a drain, a source, a gate electrode, and a nanowire between the source and drain. The nanowire has a first section with a first thickness and a second section with a second thickness greater than the first thickness. The second section is between the first section and at least one of the source or drain. The first nanowire includes a channel when a voltage is applied to the gate electrode.

A structure has stacks of semiconductor layers over a substrate and adjacent a dielectric feature. A gate dielectric is formed wrapping around each layer and the dielectric feature. A first layer of first gate electrode material is deposited over the gate dielectric and the dielectric feature. The first layer on the dielectric feature is recessed to a first height below a top surface of the dielectric feature. A second layer of the first gate electrode material is deposited over the first layer. The first gate electrode material in a first region of the substrate is removed to expose a portion of the gate dielectric in the first region, while the first gate electrode material in a second region of the substrate is preserved. A second gate electrode material is deposited over the exposed portion of the gate dielectric and over a remaining portion of the first gate electrode material.