A semiconductor device includes a semiconductor-on-insulator wafer having a buried layer. The buried layer includes therein opposing etch barrier regions and a gate region between the etch barrier regions. The semiconductor device further includes at least one nanowire having a channel portion interposed between opposing source/drain portions. The channel portion is suspended in the gate region. A gate electrode is formed in the gate region, and completely surrounds all surfaces of the suspended nanowire. The buried layer comprises a first electrical insulating material, and the etch barrier regions comprising a second electrical insulating material different from the first electrical insulating material.

Methods and structures for forming a localized, strained region of a substrate are described. Trenches may be formed at boundaries of a localized region of a substrate. An upper portion of sidewalls at the localized region may be covered with a covering layer, and a lower portion of the sidewalls at the localized region may not be covered. A converting material may be formed in contact with the lower portion of the localized region, and the substrate heated. The heating may introduce a chemical species from the converting material into the lower portion, which creates stress in the localized region. The methods may be used to form strained-channel finFETs.

A method of controlling the facet height of raised source/drain epi structures using multiple spacers, and the resulting device are provided. Embodiments include providing a gate structure on a SOI layer; forming a first pair of spacers on the SOI layer adjacent to and on opposite sides of the gate structure; forming a second pair of spacers on an upper surface of the first pair of spacers adjacent to and on the opposite sides of the gate structure; and forming a pair of faceted raised source/drain structures on the SOI, each of the faceted source/drain structures faceted at the upper surface of the first pair of spacers, wherein the second pair of spacers is more selective to epitaxial growth than the first pair of spacers.

An embodiment semiconductor device includes a nanowire extending upwards from a semiconductor substrate, a source/drain region in the nanowire, and a channel region in the nanowire over the source/drain region. The source/drain region further extends into the semiconductor substrate past edges of the nanowire. The semiconductor device further includes a gate structure encircling the channel region and a silicide in an upper portion of the source/drain region. A sidewall of the silicide is aligned with a sidewall of the gate structure.

There is provided a method for manufacturing a transistor including a gate above an underlying layer of a semiconductor material and including at least one first flank and one second flank, a gate foot formed in the underlying layer, a peripheral portion of the underlying layer surrounding the gate foot, and spacers covering at least partially the first and second flanks so as to not cover the gate foot; the method including forming the underlying layer by partially removing the semiconductor material around the gate to form the gate foot and the peripheral portion; then forming a dielectric layer for forming spacers by a deposition to cover both the first and second flanks, the gate foot, and an upper surface of the peripheral portion; and then partially removing the dielectric layer so as to expose the upper surface and so as to not expose the first and second flanks.

A method for manufacturing a transistor is provided, the transistor including a gate disposed above an underlying layer of a semiconductor material, the gate including at least one first flank and at least one second flank, and a gate foot disposed under the gate in the underlying layer and protruding relative to a peripheral portion of the underlying layer, the peripheral portion surrounding the gate foot; and the method including forming a selectivity layer obtained from an original layer and disposed only above the peripheral portion of the underlying layer, and selective etching, with respect to the selectivity layer, of the material of the original layer so as to etch the gate foot.

A quasi-lateral diffusion transistor is formed in a semiconductor-on-insulator (SOI) wafer by forming a gate region, a body region, a drift region, and a source region and bonding a handle wafer to the SOI wafer at a first side (e.g., top side) of the SOI wafer; and removing a semiconductor substrate of the SOI wafer, forming a hole in a buried insulator layer of the SOI wafer, and forming a drain region for the transistor at a second side (e.g., bottom side) of the SOI wafer. The body region and the drift region physically contact the buried insulator layer. The drain region is formed in a bottom portion of the drift region exposed by the hole and is laterally offset from the source region. In operation of the quasi-lateral diffusion transistor, a current flow direction through the semiconductor layer is diagonal between the source region and the drain region.

A method to form a semiconductor structure with an active region and a compatible dielectric layer is described. In one embodiment, a semiconductor structure has a dielectric layer comprised of an oxide of a first semiconductor material, wherein a second (and compositionally different) semiconductor material is formed between the dielectric layer and the first semiconductor material. In another embodiment, a portion of the second semiconductor material is replaced with a third semiconductor material in order to impart uniaxial strain to the lattice structure of the second semiconductor material.

An Integrated Circuit device, including: first transistors and second transistors, where the first transistors and the second transistors each include a single crystal channel, where at least one of the second transistors overlays at least one of the first transistors with less than 1 micron distance apart, and where at least one of the second transistors is a dopant segregated schottky barrier transistor.

A Method for producing a layer of strained semiconductor material, the method comprising steps for: a) formation on a substrate of a stack comprising a first semiconductor layer based on a first semiconductor material coated with a second semiconductor layer based on a second semiconductor material having a different lattice parameter to that of the first semiconductor material, b) producing on the second semiconductor layer a mask having a symmetry, c) rendering amorphous the first semiconductor layer along with zones of the second semiconductor layer without rendering amorphous one or a plurality of regions of the second semiconductor layer protected by the mask and arranged respectively opposite the masking block(s), d) performing recrystallization of the regions rendered amorphous and the first semiconductor layer resulting in this first semiconductor layer being strained (FIG. 1A).