A metal-oxide-semiconductor transistor includes a substrate, a gate insulating layer disposed on the surface of the substrate layer, a metal gate disposed on the gate insulating layer and having at least one plug hole, at least one dielectric plug disposed in the plug hole, and two diffusion regions disposed at two sides of the metal gate in the substrate. The metal gate is configured to operate under an operation voltage greater than 5 v.

A semiconductor device may include a substrate, a first nanowire, a gate electrode, a first gate spacer, a second gate spacer, a source/drain and a spacer connector. The first nanowire may be extended in a first direction and spaced apart from the substrate. The gate electrode may surround a periphery of the first nanowire, and extend in a second direction intersecting the first direction, and include first and second sidewalls opposite to each other. The first gate spacer may be formed on the first sidewall of the gate electrode. The first nanowire may pass through the first gate spacer. The second gate spacer may be formed on the second sidewall of the gate electrode. The first nanowire may pass through the second gate spacer. The source/drain may be disposed on at least one side of the gate electrode and connected with the first nanowire. The spacer connector may be disposed between the first nanowire and the substrate. The spacer connector may connect the first gate spacer and the second gate spacer to each other.

A semiconductor device includes a substrate, a gate dielectric layer on the substrate, and a gate electrode stack on the gate dielectric layer. The gate electrode stack includes a metal filling line, a wetting layer, a metal diffusion blocking layer, and a work function layer. The wetting layer is in contact with a sidewall and a bottom surface of the metal filling line. The metal diffusion blocking layer is in contact with the wetting layer and covers the sidewall and the bottom surface of the metal filling line with the wetting layer therebetween. The work function layer covers the sidewall and the bottom surface of the metal filling line with the wetting layer and the metal diffusion blocking layer therebetween.

A method for fabricating a FinFET structure comprises providing a semiconductor substrate; forming a hard mask layer on the semiconductor substrate; forming a dummy gate structure having a dummy gate, a first sidewall spacer and a second sidewall spacer; removing the dummy gate to form a first trench; forming first sub-fins in the semiconductor substrate under the hard mask layer in the first trench; forming a first metal gate structure in the first trench; removing the first sidewall spacer to form a second trench; forming second sub-fins in the semiconductor substrate under the hard mask layer in the second trench; forming a second metal gate structure in the second trench; removing the second sidewall spacer to form a third trench; forming third sub-fins in the semiconductor substrate under the hard mask layer in the third trench; and forming a third metal gate structure in the third trench.

A semiconductor device includes a substrate including a trench; a gate dielectric layer formed over a surface of the trench; a gate electrode positioned in the trench at a level lower than a top surface of the substrate, and including a first buried portion and a second buried portion over the first buried portion; and a first doping region and a second doping region formed in the substrate on both sides of the gate electrode, and overlapping with the second buried portion, wherein the first buried portion includes a first barrier which has a first work function, and the second buried portion includes a second barrier which has a second work function lower than the first work function.

A semiconductor device including: a first conductivity type transistor and a second conductivity type transistor, wherein each of the first conductivity type transistor and the second conductivity type includes agate insulating film formed on a base, a metal gate electrode formed on the gate insulating film, and side wall spacers formed at side walls of the metal gate electrode, wherein the gate insulating film is made of a high dielectric constant material, and wherein offset spacers are formed between the side walls of the metal gate electrode and the inner walls of the side wall spacers in any one of the first conductivity type transistor and the second conductivity type transistor, or offset spacers having different thicknesses are formed in the first conductivity type transistor and the second conductivity type transistor.

A Tunnel Field-Effect Transistor (TFET) is provided comprising a source-channel-drain structure of a semiconducting material. The source-channel-drain structure comprises a source region being n-type or p-type doped, a drain region oppositely doped than the source region and an intrinsic or lowly doped channel region situated between the source region and the drain region. The TFET further comprises a reference gate structure covering the channel region and a source-side gate structure aside of the reference gate structure wherein the work function and/or electrostatic potential of the source-side gate structure and the reference work function and/or electrostatic potential of the reference gate structure are selected for allowing the tunneling mechanism of the TFET device in operation to occur at the interface or interface region between the source-side gate structure and the reference gate structure in the channel region.

A method for forming MOS transistor includes providing a substrate including a semiconductor surface having a gate electrode on a gate dielectric thereon, dielectric spacers on sidewalls of the gate electrode, a source and drain in the semiconductor surface on opposing sides of the gate electrode, and a pre-metal dielectric (PMD) layer over the gate electrode and over the source and drain regions. Contact holes are formed through the PMD layer to form a contact to the gate electrode and contacts to the source and drain. A post contact etch dielectric layer is then deposited on the contacts to source and drain and on sidewalls of the PMD layer. The post contact etch dielectric layer is selectively removed from the contacts to leave a dielectric liner on sidewalls of the PMD layer. A metal silicide layer is formed on the contacts to the source and drain.

A semiconductor IC layout structure includes a plurality of first active regions arranged along a second direction, a plurality of second active regions arranged along the second direction, a plurality of gate structures extending along a first direction and respectively straddling the first active regions and the second active regions, a plurality of first conductive structures extending along the first direction, and a plurality of second conductive structures formed on the gate structures. The second active regions are isolated from the first active regions. The first direction is perpendicular to the second direction. The first conductive structures are formed on the first active regions and the second active regions. The second conductive structures include a plurality of slot-type second conductive structures extended along the second direction and a plurality of island-type second conductive structures formed on the gate structures.

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.