A semiconductor diode includes a wide bandgap semiconductor body having opposing first and second surfaces. The wide band gap semiconductor body includes a first pn junction diode having a first p-doped region adjoining the first surface and a first n-doped region adjoining both surfaces. The semiconductor diode further includes a semiconductor element including a second pn junction diode having a second p-doped region and second n-doped region, and a dielectric structure between the wide bandgap semiconductor body and semiconductor element. The dielectric structure electrically insulates the wide bandgap semiconductor body from the semiconductor element. The bandgap energy of the semiconductor element is smaller than that of the wide bandgap semiconductor body. A cathode contact is electrically connected to the first n-doped region at the second surface. The second n-doped region of the second pn junction diode is electrically coupled to the first n-doped region of the first pn junction diode.

A semiconductor component includes: a SiC semiconductor body; a trench extending from a first surface of the SiC semiconductor body into the SiC semiconductor body, the trench having a conductive connection structure, a structure width at a bottom of the trench, and a dielectric layer covering sidewalls of the trench; a shielding region along the bottom and having a central section which has a lateral first width; and a contact formed between the conductive connection structure and the shielding region. The conductive connection structure is electrically connected to a source electrode. In at least one doping plane extending approximately parallel to the bottom, a dopant concentration in the central section deviates by not more than 10% from a maximum value of the dopant concentration in the shielding region in the doping plane. The first width is less than the structure width and is at least 30% of the structure width.

A semiconductor device includes a substrate, a drift region, a well region, a first shield region, a junction gate field-effect transistor (JFET) region, a source region and a gate structure. The first shield region is located in the drift region, in which a bottom surface of the first shield region is lower than a bottom surface of the well region and a carrier concentration of the first shield region is greater than a carrier concentration of the well region. The JFET region is located in the drift region, in which a bottom surface of the JFET region is lower than a bottom surface of the first shield region. A first portion of the first shield region is located between the well region and the JFET region. The source region is adjacent to the well region. The gate structure is located on the drift region.

An integrated circuit (IC) includes a field-plated transistor including a substrate having a semiconductor surface layer, at least one body region in the semiconductor surface layer, and at least a first trench isolation region adjacent to the body region having at least a first tapered sidewall that has an average angle along its full length of 15 to 70 degrees. A gate is over the body region. A field plate is over the first tapered trench isolation region. A source is on one side of the field plate and a drain is on an opposite side of the field plate. The IC also includes circuitry for realizing at least one circuit function having a plurality of transistors which are configured together with the field-plated transistor that utilize second trench isolation regions for isolation that have an average angle of 75 and 90 degrees.

A method of fabricating a semiconductor device includes providing a substrate structure comprising a semiconductor substrate of a first conductivity type, a drift layer on the semiconductor substrate, and a fin array on the drift layer and surrounded by a recess region. The fin array comprises a first row of fins and a second row of fins parallel to each other and separated from each other by a space. The first row of fins comprises a plurality of first elongated fins extending parallel to each other in a first direction. The second row of fins comprises a plurality of second elongated fins extending parallel to each other in a second direction parallel to the first direction. The method also includes epitaxially regrowing a gate layer surrounding the first and second row of fins on the drift layer and filling the recess region.

A source layer is provided on a first p-type layer made of a nitride-based semiconductor, and includes a semiconductor region including electrons as carriers. A drain layer faces the source layer in a first direction on the first p-type layer with a gap being provided therebetween, and includes a semiconductor region including electrons as carriers. A channel structure is provided between the source layer and the drain layer on the first p-type layer, in which a channel region and a gate region are alternately disposed in a second direction perpendicular to the first direction. A channel layer included in the channel structure forms at least a part of the channel region, and is made of a nitride-based semiconductor. A gate layer included in the channel structure forms at least a part of the gate region, and electrically connects a gate electrode and the first p-type layer.

A method of forming regrown fiducials includes providing a III-V compound substrate having a device region and an alignment mark region. The III-V compound substrate is characterized by a processing surface. The method also includes forming a hardmask layer having a first set of openings in the device region exposing a first surface portion of the processing surface of the III-V compound substrate and a second set of openings in the alignment mark region exposing a second surface portion of the processing surface and etching the first surface portion and the second surface portion of the III-V compound substrate using the hardmask layer as a mask to form a plurality of trenches. The method also includes epitaxially regrowing a semiconductor layer in the trenches to form the regrown fiducials extending to a predetermined height over the processing surface in the alignment mark region.

A transistor comprising an epi layer formed within a substrate. A junction field-effect transistor implant layer formed into the epi layer. A well implant layer formed within the junction field-effect transistor implant layer. A source implant layer formed into the junction field-effect transistor implant layer. A plurality of first gate implant layers formed into the junction field-effect transistor implant layer. A plurality of first gate contacts operatively connected to the respective first gate implant layer. A source contact operatively connected to the source implant layer. A second gate contact operatively connected to the well implant layer.

A power semiconductor device according to example embodiments of the present disclosure may include: a substrate including SiC of a first conductivity type; a drift layer of the first conductivity type on the substrate; a well region of a second conductivity type on the drift layer; a drain region of the first conductivity type spaced apart inwardly from an edge of the well region by a first length and disposed in the well region; a JFET region of the first conductivity type on the drift layer outside of the well region; a gate electrode extending along an upper surface of the well region and having a ring shape, the gate electrode being disposed on the upper surface of the well region; a source electrode connected to the JFET region; and a drain electrode connected to the drain region.

A manufacturing method of a semiconductor device includes the following steps. A base region is formed in a substrate. A protective layer is formed on the substrate and covers the base region. First and second sacrificial layers are formed on the substrate and cover the protective layer. A source region, a well region, and a junction field effect transistor (JFET) region are formed in the substrate. When the source region, the well region, and the JFET region are formed in sequence, the source region and the well region are formed by the first sacrificial layer, and the JFET region is formed by the second sacrificial layer. When the JFET region, the well region, and the source region are formed in sequence, the JFET region is formed by the first sacrificial layer, and the well region and the source region are formed by the second sacrificial layer.