Provided is a semiconductor device, including: a substrate, a well region of a first conductivity type, a field region of a second conductivity type, a first doped region of the first conductivity type, and a second doped region of the second conductivity type. The well region is located in the substrate. The field region is located in the well region. The first doped region is located in the well region of a first side of the field region. The second doped region is located in the field region, wherein the first doped region is at least partially surrounded by the second doped region.

A semiconductor device comprises a silicon carbide based semiconductor layer structure that comprises a drift region having a first conductivity type and an implanted region having a second conductivity type on the drift region. First and second gate trench sections extend into the semiconductor layer structure. A first maximum depth into the semiconductor layer structure of a first portion of the implanted region that is between the first gate trench section and the second gate trench section is different than a second maximum depth into the semiconductor layer structure of a second portion of the implanted region that extends downwardly underneath the first gate trench section.

Semiconductor devices are provided that comprise a semiconductor layer structure that comprises a drift region having a first conductivity type, a channel region having a second conductivity type, and a source region having the first conductivity type. A gate trench extends into an upper surface of the semiconductor layer structure. The channel region horizontally overlaps both the gate trench and the source region.

An integrated MOSFET-JFET device made from a Silicon-Carbide (SiC) wafer has N+ source, P body diode, and upper N regions that form vertical MOSFETs on the sidewalls of polysilicon gates. An N substrate under the upper N region forms a drift region that is pinched by the JFET to limit saturation current. Trenches are formed between MOSFETs. JFETs are formed by doping the bottom and sidewalls of the trenches to form P+ taps to the N substrate. P islands within the N substrate are formed underneath the P+ taps. These P islands are wider near the surface but are successively narrower with increased vertical spacing deeper into the N substrate. This P-island tapering provides a tapered shape to the JFET depletion region that pinches the MOSFET drift region in the N substrate to limit saturation current and yet reduce linear-region ON resistance.

An integrated circuit includes a semiconductor substrate having a first type of conductivity and a semiconductor component. The semiconductor component includes: a buried semiconductor region having a second type of conductivity opposite to the first type of conductivity; a first gate region and a second gate region each extending in depth from a front face of the semiconductor substrate to the buried semiconductor region; a third gate region extending in depth from the front face of the semiconductor substrate and being electrically connected to the buried semiconductor region; and an active area delimited by the first gate region, the second gate region and the buried semiconductor region.

Semiconductor wafers, methods, and semiconductor devices are provided. In one example, a semiconductor wafer includes a polycrystalline silicon carbide substrate. The semiconductor wafer includes a wide bandgap epitaxial layer on the polycrystalline silicon carbide substrate.

A semiconductor device such as a MOSFET or IGBT comprises a semiconductor layer structure that includes a drift region having a first conductivity type, a plurality of channel regions that each have a second conductivity type, and a plurality of JFET regions that each have the first conductivity type. Each channel region comprises a ring-shaped channel region that has a ring shape and surrounds a respective one of the JFET regions when viewed in plan view.

A transistor having high field-effect mobility is provided. In order that an oxide semiconductor layer through which carriers flow is not in contact with a gate insulating film, a buried channel structure in which the oxide semiconductor layer through which carriers flow is separated from the gate insulating film is employed. Specifically, an oxide semiconductor layer having high conductivity is provided between two oxide semiconductor layers. Further, an impurity element is added to the oxide semiconductor layer in a self-aligned manner so that the resistance of a region in contact with an electrode layer is reduced. Further, the oxide semiconductor layer in contact with the gate insulating layer has a larger thickness than the oxide semiconductor layer having high conductivity.

An integrated circuit includes a semiconductor substrate having a first type of conductivity and a semiconductor component. The semiconductor component includes: a buried semiconductor region having a second type of conductivity opposite to the first type of conductivity; a first gate region and a second gate region each extending in depth from a front face of the semiconductor substrate to the buried semiconductor region; a third gate region extending in depth from the front face of the semiconductor substrate and being electrically connected to the buried semiconductor region; and an active area delimited by the first gate region, the second gate region and the buried semiconductor region.

A semiconductor device includes a semiconductor layer structure that includes an active region including a plurality of gate trenches, a plurality of gate contacts in respective ones of the gate trenches, a gate pad on the semiconductor layer structure, a gate bus extending from the gate pad, and a conductive path between the gate bus and a first one of the plurality of gate contacts. The conductive path includes a first resistivity region and at least one second resistivity region that has a higher resistivity than the first resistivity region.