The disclosure relates to a semiconductor die with a semiconductor device in a semiconductor body, the semiconductor body comprising a silicon carbide substrate; an epitaxial silicon carbide layer system on a first side of the silicon carbide substrate; an interruption layer; wherein the interruption layer is embedded either into the silicon carbide substrate or into the epitaxial silicon carbide layer system, in each case at a vertical distance from the first side of the silicon carbide substrate.

There is provided an epitaxial substrate, including: a GaN substrate whose main surface is a c-plane; and a GaN layer epitaxially grown on the main surface, wherein the main surface includes a region where an off-angle is 0.4 or more, and an E3 trap concentration in the GaN layer grown on the region is 3.010.sup.13 cm.sup.3 or less.

A semiconductor device includes substrate, a first gate structure, a second gate structure, and an epitaxy layer. The first gate structure and the second gate structure are over the substrate, in which the first gate structure and the second gate structure each comprises a shielding electrode, a gate electrode over the shielding electrode, and a first gate dielectric layer vertically separating the shielding electrode from the gate electrode. The epitaxy layer is over the substrate and cups an underside of the first gate structure and the second gate structure, in which the epitaxy layer comprises a doped region laterally between the first gate dielectric layer of the first gate structure and the first gate dielectric layer of the second gate structure, a dopant concentration of the doped region being non-uniform along a lateral direction.

An electronic device can include a substrate, an active region of a transistor, and a shield electrode. The substrate can define a trench and include a mesa adjacent to the trench, and the shield electrode can be within the trench. In an embodiment, the electronic device can further include an active region of a transistor within the mesa and an insulating layer including a thicker section and a thinner section closer to a bottom of the trench. In another embodiment, the electronic device can include a body region and a doped region within the mesa and spaced apart from the body region by a semiconductor region. The doped region can have a dopant concentration that is higher than a dopant concentration of the semiconductor region and a portion of the substrate underlying the doped region.

The present invention provides an AlGaN/GaN power HEMT device and a preparation method therefor. The device comprises: an n-type GaN substrate, a first p-type GaN layer, an AlGaN layer, a hole-injection-type PN junction layer and a gate structure, wherein the gate structure penetrates the hole-injection-type PN junction layer, the AlGaN layer and the first p-type GaN layer and stops in the n-type GaN substrate, and comprises a gate metal aluminum layer and a gate silicon dioxide layer; and the hole-injection-type PN junction layer comprises a second p-type GaN layer and a second n-type GaN layer, which are distributed in the horizontal direction, and the second n-type GaN layer is located on the side close to the gate structure.

A silicon carbide wafer and a method of fabricating the same are provided. In the silicon carbide wafer, a ratio (V:N) of a vanadium concentration to a nitrogen concentration is in a range of 2:1 to 10:1, and a portion of the silicon carbide wafer having a resistivity greater than 10.sup.12 .Math.cm accounts for more than 85% of an entire wafer area of the silicon carbide wafer.

A p-type semiconductor region is formed in a front surface side of an n-type semiconductor substrate. An n-type field stop (FS) region including protons as a donor is formed in a rear surface side of the semiconductor substrate. A concentration distribution of the donors in the FS region include first, second, third and fourth peaks in order from a front surface to the rear surface. Each of the peaks has a peak maximum point, and peak end points formed at both sides of the peak maximum point. The peak maximum points of the first and second peaks are higher than the peak maximum point of the third peak. The peak maximum point of the third peak is lower than the peak maximum point of the fourth peak.

A p-type semiconductor region is formed in a front surface side of an n-type semiconductor substrate. An n-type field stop (FS) region including protons as a donor is formed in a rear surface side of the semiconductor substrate. A concentration distribution of the donors in the FS region include first, second, third and fourth peaks in order from a front surface to the rear surface. Each of the peaks has a peak maximum point, and peak end points formed at both sides of the peak maximum point. The peak maximum points of the first and second peaks are higher than the peak maximum point of the third peak. The peak maximum point of the third peak is lower than the peak maximum point of the fourth peak.

On 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, second semiconductor regions of the second conductivity type, a gate insulating film, gate electrodes, an interlayer insulating film, first electrodes, and a second electrode are formed. Each of the first electrodes are formed by depositing a lower Ni film, an Al film, and an upper Ni film and etching the films to be apart from the interlayer insulating film; sintering the lower Ni film by a heat treatment and thereby forming a Ni silicide film; depositing a Ti film, a TiN film, and an AlSi film; and etching the AlSi film.

On 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, second semiconductor regions of the second conductivity type, a gate insulating film, gate electrodes, an interlayer insulating film, first electrodes, and a second electrode are formed. Each of the first electrodes are formed by depositing a lower Ni film, an Al film, and an upper Ni film and etching the films to be apart from the interlayer insulating film; sintering the lower Ni film by a heat treatment and thereby forming a Ni silicide film; depositing a Ti film, a TiN film, and an AlSi film; and etching the AlSi film.