A switching device including: a body of semiconductor material, which has a first conductivity type and is delimited by a front surface; a contact layer of a first conductive material, which extends in contact with the front surface; and a plurality of buried regions, which have a second conductivity type and are arranged within the semiconductor body, at a distance from the contact layer.

A silicon carbide semiconductor device includes a silicon carbide semiconductor substrate of a first conductivity type, a first semiconductor layer of the first conductivity type, a second semiconductor layer of a second conductivity type, first semiconductor regions of the first conductivity type, trenches, a gate insulating film, gate electrodes, and an interlayer insulating film. The gate insulating film is formed by performing nitriding and oxidation by at least two sessions of a heat treatment by a mixed gas containing nitric oxide and nitrogen, the gate insulating film being configured by a first gate insulating film that is a silicon nitride layer, a second gate insulating film that is a silicon oxide film, and a third gate insulating film that is a silicon oxide film having a nitrogen area density lower than that of the second gate insulating film.

A method for fabricating a silicon carbide semiconductor device includes providing a SiC epitaxial layer disposed over a surface of a SiC substrate, forming an implant aperture in a hardmask layer on a surface of the expitaxial SiC layer, implanting contact and well regions in the SiC epitaxial layer through the hardmask layer, the contact region lying completely within and recessed from edges of the well region by performing one of implanting the well region through the implant aperture, reducing the area of the implant aperture forming a reduced-area contact implant aperture and implanting the contact region through the reduced-area implant aperture to form a contact region, and implanting the contact region through the implant aperture, increasing the area of the implant aperture to form a increased-area well implant aperture and implanting the well region through the increased-area implant aperture to form a well region completely surrounding the contact region.

SiC Schottky rectifier 100 with surge current ruggedness. As referenced above, the Schottky rectifier 100 may be configured to provide multiple types of surge current protection.

A Schottky device includes a silicon carbide (SiC) substrate of a first conductivity type, a drift layer of the first conductivity type, a trench, a barrier layer of a second conductivity type, an electrically conductive material that at least partially fills the trench and contacts the barrier layer, a first electrode, and a second electrode. The drift layer is formed of SiC and is situated onto the SiC substrate. The trench extends from the top surface of the drift layer towards the SiC substrate. The barrier layer contacts the drifting layer and covers a sidewall and a bottom wall of the trench. The first electrode forms a Schottky junction with the drift layer and forms a low resistivity contact with the barrier layer and the electrically conductive material. The second electrode forms an ohmic contact with the SiC substrate.

A semiconductor device includes a contact metallization layer arranged on a semiconductor substrate, an inorganic passivation structure arranged on the semiconductor substrate, and an organic passivation layer. The organic passivation layer is located between the contact metallization layer and the inorganic passivation structure, and located vertically closer to the semiconductor substrate than a part of the organic passivation layer located on top of the inorganic passivation structure.

A method and apparatus include an n-doped layer having a first applied charge, and a p.sup.−-doped layer having a second applied charge. The p.sup.−-doped layer may be positioned below the n-doped layer. A p.sup.+-doped buffer layer may have a third applied charge and be positioned below the p.sup.−-doped layer. The respective charges at each layer may be determined based on a dopant level and a physical dimension of the layer. In one example, the n-doped layer, the p.sup.−-doped layer, and the p.sup.+-doped buffer layer comprise a lateral semiconductor manufactured from silicon carbide (SiC).

A method for manufacturing an electronic device based on SiC includes forming a structural layer of SiC on a front side of a substrate. The substrate has a back side that is opposite to the front side along a direction. Active regions of the electronic device are formed in the structure layer, and the active regions are configured to generate or conduct electric current during the use of the electronic device. A first electric terminal is formed on the structure layer, and an intermediate layer is formed at the back side of the substrate. The intermediate layer is heated by a LASER beam in order to generate local heating such as to favor the formation of an ohmic contact of Titanium compounds. A second electric terminal of the electronic device is formed on the intermediate layer.

Semiconductor devices include a silicon carbide drift region having an upper portion and a lower portion. A first contact is on the upper portion of the drift region and a second contact is on the lower portion of the drift region. The drift region includes a superjunction structure that includes a p-n junction that is formed at an angle of between 10° and 30° from a plane that is normal to a top surface of the drift region. The p-n junction extends within +/−1.5° of a crystallographic axis of the silicon carbide material forming the drift region.

A semiconductor product, including: a base region doped with a first conductivity type; a plurality of stripe regions doped with a second conductivity type, provided on an upper surface of the base region, and the second conductivity type is different from the first conductivity type; a plurality of cell regions doped with the second conductivity type, provided on the upper surface of the base region; and a metal layer arranged on the upper surface of the base region, so that the metal layer defines a Schottky barrier with the base region and covers the plurality of stripe regions and the plurality of cell regions; and each cell region of a majority of the plurality of cell regions contacts at least one neighboring stripe region of the plurality of stripe regions and the stripe regions and the cell regions extend into the base region to different depths.