Provided are: injection control regions of a second conductivity type provided on a charge transport region of a first conductivity type; main electrode regions of the first conductivity type provided on the injection control regions; insulated gate electrode structures going through the main electrode region and the injection control regions in the depth direction; an injection suppression region going through the main electrode regions and the injection control regions in the depth direction so as to form a pn junction in a path leading to the charge transport region, the injection suppression region including a semiconductor material with a narrower bandgap than a material of the charge transport region; and a contact protection region of the second conductivity type contacting the bottom surface of the injection suppression region.

A semiconductor structure and method of manufacture is provided. In some embodiments, a semiconductor structure includes a semiconductor layer comprising a first uppermost surface, a lowermost surface, and a first sidewall surface extending between the uppermost surface and the lowermost surface. A gate dielectric layer is over the semiconductor layer. A first gate electrode is over a portion of the gate dielectric layer over the uppermost surface of the semiconductor layer. A first source/drain region is in the semiconductor layer under the first uppermost surface and adjacent the first gate electrode. A second source/drain region is in the semiconductor layer under the lowermost surface of the semiconductor layer.

A method for producing a semiconductor component includes: forming a silicon carbide substrate having a body layer formed on a section of a main layer, and a source layer formed on a section of the body layer; forming gate trenches and contact trenches extending through the source layer and the body layer, the gate trenches and contact trenches alternating along a first horizontal direction parallel to a first main surface of the silicon carbide substrate; forming a gate dielectric in the gate trenches; forming a metal structure which includes first sections adjoining the gate dielectric in the gate trenches and second sections in the contact trenches, the second sections adjoining body regions formed from sections of the body layer and source regions formed from sections of the source layer; and removing third sections of the metal structure that connect the first sections to the second sections.

High-voltage semiconductor devices are disclosed, each having gate, source and drain electrodes. A deep well layer is formed on a substrate and has a surface, where the substrate and the deep well layer are of first-type and second-type conductivities, respectively. A field isolation layer on the surface isolates a drain active region from a source active region. The source electrode contacts the source active region on the surface to form an ohmic contact. The drain electrode contacts the drain active region on the surface. A first well layer of the first-type conductivity is formed on the surface and between the ohmic contact and the drain active region, and at least a portion of the first well layer is under the field isolation layer. A bottom layer of the first-type conductivity is formed at a bottom of the deep well layer. The gate electrode is on the field isolation layer.

A semiconductor device including an insulating layer on a substrate; channel semiconductor patterns stacked on the insulating layer and vertically spaced apart from each other; a gate electrode crossing the channel semiconductor patterns; source/drain regions respectively at both sides of the gate electrode and connected to each other through the channel semiconductor patterns, the source/drain regions having concave bottom surfaces; and air gaps between the insulating layer and the bottom surfaces of the source/drain regions.

A power semiconductor is provided. The power semiconductor includes a gate, a source, a silicon chip and a drain. The source includes a first copper particle layer and a first metal layer. The first copper particle layer covers the upper surface of the first metal layer. The silicon chip is bonded to the lower surface of the first metal layer. The drain is bonded to the lower surface of the silicon chip. The thickness of the first copper particle layer is greater than the thickness of the first metal layer. All copper mentioned are of large grain copper with size greater than 0.25 um.

The semiconductor layout structure includes an active region surrounded by an isolation structure, at least one first gate structure disposed over the active region and the isolation structure, at least one second gate structure disposed over the active region and the isolation structure, and a plurality of source/drain regions disposed in the active region. The active region includes two first regions, a second region disposed between the two first regions, a third region disposed between one of the first region and the second region, and a fourth region disposed between the other first region and the second region.

A semiconductor device, includes a first conductive type first doping area, a second conductive type second doping area, a source region, a drain region, a gate insulating film, and a gate electrode. The first conductive type first doping area is formed in a substrate region. The second conductive type second doping area is formed in the substrate to be spaced apart from the first conductive type first doping area. The source region is formed in the first conductive type first doping area. The drain region is formed in the second conductive type second doping area. The gate insulating film is formed between the source region and the drain region. A thickness of a first end of the gate insulating film is different than a thickness of a second end of the gate insulating film. The gate electrode formed on the gate insulating film.

A method and apparatus for reducing dynamic switching current in high speed logic. The apparatus may include a CMOS logic circuit, which in turn includes an NMOS FinFET, a first PMOS FinFET, and a second PMOS FinFET. A gate of the NMOS FinFET is connected to a gate of the first PMOS FinFET, a drain of the NMOS FinFET is connected to a drain of the first PMOS FinFET, and the second PMOS FinFET is connected to the first PMOS FinFET to create a capacitor between a source and the drain of the first PMOS FinFET. In one embodiment, the second PMOS FinFET is contained in and positioned at an edge of a cell that also contains the first PMOS FinFET and the NMOS FinFET.

A semiconductor device includes a source region. A drain region has a first conductivity type and a second dopant concentration spaced apart from the source region. A first drift region is located between the source region and the drain region and has the first conductivity type and a first dopant concentration that is lower than the second dopant concentration of the drain region. An oxide structure includes a first portion on or over the first drift region and a tapered portion between the first portion and the drain region. A substrate surface extension is between the tapered portion and the drain region. A buffer region has the first conductivity type between the first drift region and the drain region and under the tapered portion of the oxide structure. The buffer region has a third dopant concentration between the second dopant concentration and the first dopant concentration.