Semiconductor device and the manufacturing method thereof are disclosed. An exemplary semiconductor device comprises a semiconductor stack including semiconductor layers over a substrate, wherein the semiconductor layers are separated from each other and are stacked up along a direction substantially perpendicular to a top surface of the substrate; an isolation structure around a bottom portion of the semiconductor stack and separating active regions; a metal gate structure over a channel region of the semiconductor stack and wrapping each of the semiconductor layers; a gate spacer over a source/drain (S/D) region of the semiconductor stack and along sidewalls of a top portion of the metal gate structure; and an inner spacer over the S/D region of the semiconductor stack and along sidewalls of lower portions of the metal gate structure and wrapping edge portions of each of the semiconductor layers.

Source and drain formation techniques disclosed herein provide FinFETs with reduced channel resistance and reduced drain-induced barrier lowering. An exemplary three-step etch method for forming a source/drain recess in a source/drain region of a fin includes a first anisotropic etch, an isotropic etch, and a second anisotropic etch. The first anisotropic etch and the isotropic etch are tuned to define a location of a source/drain tip. A depth of the source/drain recess after the first anisotropic etch and the isotropic etch is less than a target depth. The second anisotropic etch is tuned to extend the depth of the source/drain recess to the target depth. The source/drain tip is near a top of the fin to reduce channel resistance while a bottom portion of the source/drain recess is spaced a distance from a gate footing that can minimize DIBL. The source/drain recess is filled with an epitaxial semiconductor material.

A semiconductor device includes a first fin and a second fin in a first direction and aligned in the first direction over a substrate, an isolation insulating layer disposed around lower portions of the first and second fins, a first gate electrode extending in a second direction crossing the first direction and a spacer dummy gate layer, and a source/drain epitaxial layer in a source/drain space in the first fin. The source/drain epitaxial layer is adjacent to the first gate electrode and the spacer dummy gate layer with gate sidewall spacers disposed therebetween, and the spacer dummy gate layer includes one selected from the group consisting of silicon nitride, silicon oxynitride, silicon carbon nitride, and silicon carbon oxynitride.

Semiconductor device and the manufacturing method thereof are disclosed. An exemplary semiconductor device comprises a first semiconductor stack and a second semiconductor stack over a substrate, wherein each of the first and second semiconductor stacks includes semiconductor layers stacked up and separated from each other; a dummy spacer between the first and second semiconductor stacks, wherein the dummy spacer contacts a first sidewall of each semiconductor layer of the first and second semiconductor stacks; and a gate structure wrapping a second sidewall, a top surface, and a bottom surface of each semiconductor layer of the first and second semiconductor stacks.

Various examples of an integrated circuit device and a method for forming the device are disclosed herein. In an example, a method includes receiving a workpiece that includes a substrate, and a device fin extending above the substrate. The device fin includes a channel region. A portion of the device fin adjacent the channel region is etched, and the etching creates a source/drain recess and forms a dielectric barrier within the source/drain recess. The workpiece is cleaned such that a bottommost portion of the dielectric barrier remains within a bottommost portion of the source/drain recess. A source/drain feature is formed within the source/drain recess such that the bottommost portion of the dielectric barrier is disposed between the source/drain feature and a remainder of the device fin.

A fin-type field-effect transistor device includes a substrate, insulators, gate stacks and dielectric strips. The substrate includes a first doped region, a second doped region, third doped blocks located above the first doped region and fourth doped blocks located above the second doped region, and fins located above the third doped blocks and the fourth doped blocks, wherein doping concentrations of the third doped blocks are lower than a doping concentration of the first doped region, and doping concentrations of the fourth doped blocks are lower than a doping concentration of the second doped region. The insulators are disposed on the third doped blocks and the fourth doped blocks of the substrate and covering the fins. The dielectric strips are disposed in between the fins, and in between the third doped blocks and the fourth doped blocks. The gate stacks are disposed over the fins and above the insulators.

Semiconductor devices and methods of forming the same are provided. A method includes providing a workpiece having a semiconductor structure; depositing a two-dimensional (2D) material layer over the semiconductor structure; forming a source feature and a drain feature electrically connected to the semiconductor structure and the 2D material layer, wherein the source feature and drain feature include a semiconductor material; and forming a gate structure over the two-dimensional material layer and interposed between the source feature and the drain feature. The gate structure, the source feature, the drain feature, the semiconductor structure and the 2D material layer are configured to form a field-effect transistor. The semiconductor structure and the 2D material layer function, respectively, as a first channel and a second channel between the source feature and the drain feature.

A semiconductor device includes a silicon carbide layer including an element region, a termination region surrounding the element region, a first semiconductor part including a first portion in the element region, and a second semiconductor part located on the first semiconductor part in a first direction, the second semiconductor part being adjacent to the first portion in a second direction; a gate electrode facing the second semiconductor part of the element region; a first insulating film located between the gate electrode and the silicon carbide layer; and a second insulating film located on the first portion of the first semiconductor part, the second insulating film being thicker than the first insulating film.

In the present invention, there is provided a semiconductor device including: element isolation regions formed in a state of being buried in a semiconductor substrate such that an element formation region of the semiconductor substrate is interposed between the element isolation regions; a gate electrode formed on the element formation region with an gate insulating film interposed between the gate electrode and the element formation region, the gate electrode being formed so as to cross the element formation region; and source-drain regions formed in the element formation region on both sides of the gate electrode, wherein a channel region made of the element formation region under the gate electrode is formed so as to project from the element isolation regions, and the source-drain regions are formed to a position deeper than surfaces of the element isolation regions.

Semiconductor devices and corresponding methods of manufacturing the same are disclosed. For example, a plurality of first semiconductor channels vertically spaced from one another and a plurality of second semiconductor channels vertically spaced from one another can be provided. The plurality of first semiconductor channels each have a first sidewall in contact with a first dielectric structure and the plurality of second semiconductor channels each have a first sidewall in contact with a second dielectric structure. A cavity can be formed between the first sidewalls of the plurality of first and second semiconductor channels. Gate structures can be formed around at least a top surface, a bottom surface, and a second sidewall of the first and second semiconductor channels.