A semiconductor device includes a silicon carbide semiconductor body. A first shielding region of a first conductivity type is connected to a first contact at a first surface of the silicon carbide semiconductor body. A current spread region of a second conductivity type is connected to a second contact at a second surface of the silicon carbide semiconductor body. A doping concentration profile of the current spread region includes peaks along a vertical direction perpendicular to the first surface. A doping concentration of one peak or one peak-group of the peaks is at least 50% higher than a doping concentration of any other peak of the current spread region. A vertical distance between the one peak or the one peak-group of the current spread region and the first surface is larger than a second vertical distance between the first surface and a maximum doping peak of the first shielding region.

A silicon carbide power device has: a die having a functional layer of silicon carbide and an edge area and an active area, surrounded by the edge area; gate structures formed on a top surface of the functional layer in the active area; and a gate contact pad for biasing the gate structures. The device also has an integrated resistor having a doped region, of a first conductivity type, arranged at the front surface of the functional layer in the edge area; wherein the integrated resistor defines an insulated resistance in the functional layer, interposed between the gate structures and the gate contact pad.

For the manufacturing of a vertical conduction silicon carbide electronic device, a work wafer, which has a silicon carbide substrate having a work face, is processed. A rough face is formed from the work face of the silicon carbide substrate. The rough face has a roughness higher than a threshold. A metal layer is deposited on the rough face and the metal layer is annealed, thereby causing the metal layer to react with the silicon carbide substrate, forming a silicide layer having a plurality of protrusions of silicide.

An n.sup.--type drift layer is an n.sup.--type epitaxial layer doped with nitrogen as an n-type dopant and is co-doped with aluminum as a p-type dopant, the n.sup.--type drift layer containing the nitrogen and aluminum substantially uniformly throughout. An n-type impurity concentration of the n.sup.--type drift layer is an impurity concentration determined by subtracting the aluminum concentration from the nitrogen concentration of the n.sup.--type drift layer; a predetermined blocking voltage is realized by the impurity concentration. A combined impurity concentration of the nitrogen and aluminum of the n.sup.--type drift layer is at least 3×10.sup.16/cm.sup.3.

A semiconductor device includes a first MOS structure portion that includes, as its elements, a semiconductor substrate of a first conductivity type, a first semiconductor layer of the first conductivity type, a first second-semiconductor-layer of a second conductivity type, first semiconductor regions of the first conductivity type, and first gate insulating films, and a second MOS structure portion that includes, as its elements, the substrate, the first semiconductor layer, a second second-semiconductor-layer, second first-semiconductor-regions of the first conductivity type, and second gate insulating films. First and second portions include all of the elements of the first and second MOS structure portions other than the first and second first-semiconductor-regions and the first and second gate insulating films, respectively. A structure of one of the elements of the first portion is not identical to a structure of a corresponding element of the second portion.

Junction field effect transistors (JFETs) and related manufacturing methods are disclosed herein. A disclosed JFET includes a vertical channel region located in a mesa and a first channel control region located on a first side of the mesa. The first channel control region is at least one of a gate region and a first base region. The JEFT also includes a second base region located on a second side of the mesa and extending through the mesa to contact the vertical channel region. The vertical channel can be an implanted vertical channel. The vertical channel can be asymmetrically located in the mesa towards the first side of the mesa.

The fabrication method for a silicon carbide semiconductor device according to this disclosure includes a step of forming a dielectric film over part of a silicon carbide layer, a step of forming an ohmic electrode adjoining the dielectric film on the silicon carbide layer, a step of removing an oxidized layer on the ohmic electrode, a step of forming a mask with its opening on the side opposite to the side where the ohmic electrode is adjoining the dielectric film on the ohmic electrode having the oxidized layer removed and on the dielectric film, and a step of wet etching of a film to be etched with hydrofluoric acid with the mask formed. With the fabrication method for a silicon carbide semiconductor device described in this disclosure, it is possible to fabricate a silicon carbide semiconductor device with reduced failure.

A semiconductor device includes a SiC substrate and a plurality of transistor cells formed in the SiC substrate and electrically connected in parallel to form a transistor. Each transistor cell includes a gate structure including a gate electrode and a gate dielectric stack separating the gate electrode from the SiC substrate. The gate dielectric stack includes a ferroelectric insulator. The transistor has a specified operating temperature range, and the ferroelectric insulator is doped with a doping material such that the Curie temperature of the ferroelectric insulator is in a range above the specified operating temperature range of the transistor. A corresponding method of producing the semiconductor device is also described.

Provided is a method of manufacturing a semiconductor device capable of suppressing variation in thickness of oxide films among a plurality of SiC wafers. Forming first inorganic films on lower surfaces of a plurality of SiC wafer, and then performing etching of the plurality of SiC wafers so that 750 nm or more of the first inorganic film is left in thickness, and then forming oxide films on upper surfaces of the plurality of SiC wafers by performing thermal oxidation treatment in a state in which a first SiC wafer of the plurality of SiC wafers is placed directly below any one of at least one wafer, including at least one of a dummy wafer and a monitor wafer, and a second SiC wafer of the plurality of SiC wafers is placed directly below a third SiC wafer of the plurality of SiC wafers.

A silicon carbide semiconductor device includes a silicon carbide (SiC) substrate having a SiC epitaxial layer disposed over a surface of the SiC substrate, the SiC substrate having a first conductivity and the SiC epitaxial layer having the first conductivity. A contact region and a well region are formed in the SiC epitaxial layer, the contact region and the well region have a doping level of a second conductivity opposite the first conductivity. The contact region lies completely within the well region, is not in contact with a region having the first conductivity and has edges recessed from edges of the well region.