A nitride semiconductor device is disclosed. The semiconductor device provides the GaN channel layer, the InAlN barrier layer on the GaN channel layer, and the n-type AlGaN layer on the InAlN barrier layer. The source and drain electrodes are formed on the n-type AlGaN layer, while, the gate electrode is formed directly on the InAlN barrier layer. The n-type AlGaN layer has the aluminum (Al) composition greater than 20% at the interface against the InAlN barrier layer, which is greater than the aluminum (Al) composition at the interface against the source electrode.

A semiconductor device includes a semiconductor mesa that includes at least one body zone forming first pn junctions with source zones and a second pn junction with a drift zone. Electrode structures are on opposite sides of the semiconductor mesa. At least one of the electrode structures includes a gate electrode configured to control a charge carrier flow through the at least one body zone. In a separation region between the source zones, which are arranged along an extension direction of the semiconductor mesa, the semiconductor mesa includes at least one partial or complete constriction.

An embodiment high electron mobility transistor (HEMT) includes a gate electrode over a semiconductor substrate and a multi-layer semiconductor cap over the semiconductor substrate and adjacent the gate electrode. The multi-layer semiconductor cap includes a first semiconductor layer and a second semiconductor layer comprising a different material than the first semiconductor layer. The first semiconductor layer is laterally spaced apart from the gate electrode by a first spacing, and the second semiconductor layer is spaced apart from the gate electrode by a second spacing greater than the first spacing.

A semiconductor structure includes a substrate with a plurality of word line trenches and source/drain regions each adjacent to each word line trench; a word line located in the word line trench, which includes a first conductive layer located at a bottom of the word line trench, a single junction layer and a second conductive layer stacked in sequence, in which a projection of the word line on a sidewall of the word line trench and the projection of the source/drain region on the sidewall of the word line trench have an overlapping region with a preset height, and when a voltage applied to the word line is less than a preset voltage, a resistance of the single junction layer is greater than the preset resistance, to make the first conductive layer and the second conductive layer disconnected.

Embodiments of semiconductor assemblies, and related integrated circuit devices and techniques, are disclosed herein. In some embodiments, a semiconductor assembly may include a flexible substrate, a first barrier formed of a first transition metal dichalcogenide (TMD) material, a transistor channel formed of a second TMD material, and a second barrier formed of a third TMD material. The first barrier may be disposed between the transistor channel and the flexible substrate, the transistor channel may be disposed between the second barrier and the first barrier, and a bandgap of the transistor channel may be less than a bandgap of the first barrier and less than a bandgap of the second barrier. Other embodiments may be disclosed and/or claimed.

The present invention discloses a high voltage JFET. The high voltage JFET includes a second conductivity type drift region located on the first conductivity type epitaxial layer; a second conductivity type drain heavily doped region located in the second conductivity type drift region; a drain terminal oxygen region located on the second conductivity type drift region and at a side of the second conductivity type drain heavily doped region; a first conductivity type well region located at a side of the second conductivity type drift region; a second conductivity type source heavily doped region and a first conductivity type gate heavily doped region located on the first conductivity type well region, and a gate source terminal oxygen region; a second conductivity type channel layer located between the second conductivity type source heavily doped region and the second conductivity type drift region; a dielectric layer and a field electrode plate located on the second conductivity type channel layer. Wherein a drain electrode electrically is led out from the second conductivity type drain heavily doped region; a source electrode electrically is led out from a connection of the field electrode plate and the second conductivity type source heavily doped region; and a gate electrode electrically is led out from the first conductivity type gate heavily doped region. The transistor has a high breakdown voltage and easy to be integrated.

A semiconductor device includes a gate structure located on a substrate and a raised source/drain region adjacent to the gate structure. The raised source/drain region includes: a first epitaxial-grown doped layer of the raised source/drain region in contact with the substrate; a second epitaxial-grown doped layer on the first epitaxial-grown doped layer and including a same dopant species as the first epitaxial-grown doped layer, wherein the second epitaxial-grown doped layer includes a higher dopant concentration than the first epitaxial-grown doped layer and interfacing the gate structure by using a predetermined distance; and a third epitaxial-grown doped layer on the second epitaxial-grown doped layer and including the same dopant species as the first epitaxial-grown doped layer, wherein the third epitaxial-grown doped layer includes a higher dopant concentration than the second epitaxial-grown doped layer.

Device architectures based on trapping and de-trapping holes or electrons and/or recombination of both types of carriers are obtained by carrier trapping either in near-interface deep ambipolar states or in quantum wells/dots, either serving as ambipolar traps in semiconductor layers or in gate dielectric/barrier layers. In either case, the potential barrier for trapping is small and retention is provided by carrier confinement in the deep trap states and/or quantum wells/dots. The device architectures are usable as three terminal or two terminal devices.

A nitride semiconductor device according to one embodiment of the present disclosure includes: a substrate; a first nitride semiconductor layer supported by the substrate; a second nitride semiconductor layer disposed on the first nitride semiconductor layer; a source-side nitride semiconductor regrowth layer which is located on a source-side recess region; a drain-side nitride semiconductor regrowth layer which is located on a drain-side recess region located apart from the source-side recess region; a first diffusion layer which is disposed in the first nitride semiconductor layer and contains Ge diffused from the source-side nitride semiconductor regrowth layer; and a second diffusion layer which is disposed in the first nitride semiconductor layer and contains Ge diffused from the drain-side nitride semiconductor regrowth layer.

An embodiment high electron mobility transistor (HEMT) includes a gate electrode over a semiconductor substrate and a multi-layer semiconductor cap over the semiconductor substrate and adjacent the gate electrode. The multi-layer semiconductor cap includes a first semiconductor layer and a second semiconductor layer comprising a different material than the first semiconductor layer. The first semiconductor layer is laterally spaced apart from the gate electrode by a first spacing, and the second semiconductor layer is spaced apart from the gate electrode by a second spacing greater than the first spacing.