An asymmetric high-k dielectric for reduced gate induced drain leakage in high-k MOSFETs and methods of manufacture are disclosed. The method includes performing an implant process on a high-k dielectric sidewall of a gate structure. The method further includes performing an oxygen annealing process to grow an oxide region on a drain side of the gate structure, while inhibiting oxide growth on a source side of the gate structure adjacent to a source region.

A semiconductor structure is disclosed that includes a semiconductor structure includes an active area, a first conductive line, a conductive via, a first conductive metal segment coupled to the conductive line through the conductive via, a second conductive metal segment disposed over the active area, and a local conductive segment configured to couple the first conductive metal segment and the second conductive metal segment.

Metal-oxide-semiconductor (MOS) transistors with reduced subthreshold conduction, and methods of fabricating the same. Transistor gate structures are fabricated in these transistors of a shape and dimension as to overlap onto the active region from the interface between isolation dielectric structures and the transistor active areas. Minimum channel length conduction is therefore not available at the isolation-to-active interface, but rather the channel length along that interface is substantially lengthened, reducing off-state conduction.

Methods for fabricating integrated circuits are provided. In one example, a method for fabricating an integrated circuit includes forming an isolation trench between two fin structures on an integrated circuit substrate, forming a flowable film in the isolation trench using a flowable chemical vapor deposition process, and annealing the flowable film to form a silicon oxide dielectric layer in the isolation trench. The annealing is performed at a temperature of less than about 200 C. with a process gas including N.sub.2 and H.sub.2O.sub.2.

A method for producing a semiconductor device includes forming a fin-shaped semiconductor layer on a substrate, forming a first insulating film around the fin-shaped semiconductor layer, and a first metal film is formed around the first insulating film. A pillar-shaped semiconductor layer is formed on the fin-shaped semiconductor layer and a gate insulating film is formed around the pillar-shaped semiconductor layer. A gate electrode is formed around the gate insulating film, the gate electrode being made of a third metal, and a gate line is connected to the gate electrode. A second insulating film is formed around a sidewall of an upper portion of the pillar-shaped semiconductor layer, and a second metal film is formed around the second insulating film.

A semiconductor device includes a fin-shaped semiconductor layer, a first insulating film around the fin-shaped semiconductor layer, and a first metal film around the first insulating film. A pillar-shaped semiconductor layer is on the fin-shaped semiconductor layer, and a gate insulating film is around the pillar-shaped semiconductor layer. A gate electrode is around the gate insulating film and is made of a third metal. A gate line is connected to the gate electrode, and an upper portion of the fin-shaped semiconductor layer and the first metal film are electrically connected to each other.

An SGT is produced by forming a first insulating film around a fin-shaped semiconductor layer, forming a pillar-shaped semiconductor layer in an upper portion of the fin-shaped layer, forming a second insulating film, a polysilicon gate electrode covering the second insulating film, and a polysilicon gate line, forming a diffusion layer in an upper portion of the fin-shaped layer and a lower portion of the pillar-shaped layer, forming a metal-semiconductor compound in an upper portion of the diffusion layer in the fin-shaped layer, depositing an interlayer insulating film, exposing and etching the polysilicon gate electrode and gate line, depositing a first metal, forming a metal gate electrode and a metal gate line, and forming a third metal sidewall on an upper side wall of the pillar-shaped layer. The third metal sidewall is connected to an upper surface of the pillar-shaped layer.

The present invention provides a thin-film transistor in which transistor characteristics such as drain current and threshold voltage are improved, and a method of manufacturing the same. The present invention provides a thin-film transistor provided with a source electrode (108), a drain electrode (109), a semiconductor layer (105), a gate electrode (103), and an insulating layer (104); wherein the semiconductor layer (105) contains a composite metal oxide obtained by adding to a first metal oxide an oxide having an oxygen dissociation energy that is at least 200 kJ/mol greater than the oxygen dissociation energy of the first metal oxide, whereby the amount of oxygen vacancy is controlled; and the insulating layer (104) is provided with an SiO.sub.2 layer, a high-permittivity first layer, and a high-permittivity second layer, whereby the dipoles generated at the boundary between the SiO.sub.2 layer and the high-permittivity layers are used to control the threshold voltage.

A semiconductor device may include a strain relaxed buffer layer provided on a substrate to contain silicon germanium, a semiconductor pattern provided on the strain relaxed buffer layer to include a source region, a drain region, and a channel region connecting the source region with the drain region, and a gate electrode enclosing the channel region and extending between the substrate and the channel region. The source and drain regions may contain germanium at a concentration of 30 at % or higher.

Disclosed is a semiconductor device, including: a first pipe gate; a second pipe gate on the first pipe gate; a stacked structure on the second pipe gate; a first channel layer including a first pipe channel layer positioned within the first pipe gate and first cell channel layers connected to the first pipe channel layer; a second channel layer including a second pipe channel layer positioned within the second pipe gate, and second cell channel layers connected to the second pipe channel layer; and a slit insulating layer passing through the stacked structure and positioned between the adjacent second cell channel layers, wherein the second pipe channel layer has a body portion and a protrusion portion extending below the body portion at a position below the slit insulating layer.