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.

Energy-filtered cold electron devices use electron energy filtering through discrete energy levels of quantum wells or quantum dots that are formed through band bending of tunneling barrier conduction band. These devices can obtain low effective electron temperatures of less than or equal to 45K at room temperature, steep electrical current turn-on/turn-off capabilities with a steepness of less than or equal to 10 mV/decade at room temperature, subthreshold swings of less than or equal to 10 mV/decade at room temperature, and/or supply voltages of less than or equal to 0.1 V.

A semiconductor device including a semiconductor substrate including a plurality of active regions and a device isolation region for isolating the plurality of active regions; and a buried bit line and a buried gate electrode which are formed in the semiconductor substrate. The device isolation region includes a first device isolation region extending in a first direction and a second device isolation region extending in a second direction crossing with the first direction and having a shield pillar formed therein.

A device includes a vertical transistor comprising a first buried layer over a substrate, a first well over the first buried layer, a first gate in a first trench, wherein the first trench is formed partially through the first buried layer, and wherein a dielectric layer and the first gate are in the first trench, a second gate in a second trench, wherein the second trench is formed partially through the first buried layer, and wherein the second trench is of a same depth as the first trench, a first drain/source region and a second drain/source region formed on opposite sides of the first trench and a first lateral transistor comprising a second buried layer formed over the substrate, a second well over the second buried layer and drain/source regions over the second well.

A semiconductor component including: a semiconductor substrate; and a semiconductor device provided thereon, the device being a field-effect transistor that includes: a gate insulating film provided on the substrate; a gate electrode provided via the film; and a pair of source-drain regions provided to sandwich the electrode, the substrate including a patterned surface in a portion where the electrode is provided, the patterned surface of the substrate including a raised portion where the film is formed to cover a surface that lies on the same plane as a surface of the pair of source-drain regions, and the electrode is formed on a top surface of the film, and the patterned surface of the substrate including a recessed portion where the film is formed to cover surfaces of a groove formed toward the interior than the surface of the pair of source-drain regions, and the electrode is formed so as to fill the groove provided with the film.

Disclosed is a power device, such as power MOSFET, and method for fabricating same. The device includes an upper trench situated over a lower trench, where the upper trench is wider than the lower trench. The device further includes a trench dielectric inside the lower trench and on sidewalls of the upper trench. The device also includes an electrode situated within the trench dielectric. The trench dielectric of the device has a bottom thickness that is greater than a sidewall thickness.

A semiconductor device includes a semiconductor substrate comprising a main surface and a gate electrode in a trench between neighboring semiconductor mesas, The gate electrode is electrically insulated from the neighboring semiconductor mesas by a dielectric layer. The semiconductor device further includes a conductor arranged, at least partially, between neighboring dielectric contact spacers. The conductor has a conductivity greater than a conductivity of the gate electrode, An interface between the conductor and the gate electrode extends along the gate electrode.

Methods for forming a transistor include forming a gate conductor in contact with a gate stack. The gate conductor has a top surface that meets a middle point of sidewalls of a sacrificial region of a fin. The sacrificial region of the fin is trimmed to create gaps above the gate stack. A top spacer is formed on the gate conductor. The top spacer includes airgaps above the gate stack.

A transistor includes a vertical channel fin directly on a bottom source/drain region. A gate stack is formed on sidewalls of the vertical channel fin. A top spacer is formed over the gate stack. The top spacer has air gaps directly above the gate stack. A top source/drain region is formed directly on a top surface of the vertical channel fin.