A power semiconductor device includes: a semiconductor body for conducting a load current between first and second load terminals; source and channel regions and a drift volume in the semiconductor body; a semiconductor zone in the semiconductor body and coupling the drift volume to the second load terminal, a first transition established between the semiconductor zone and the drift volume; a control electrode insulated from the semiconductor body and the load terminals and configured to control a path of the load current in the channel region; and a trench extending into the drift volume along an extension direction and including a field electrode. An ohmic resistance of the field electrode is greater than an ohmic resistance of the control electrode. A distance between the field electrode and the first transition is at least 70% of the total extension of the drift volume in the extension direction.

A group III-N nanowire is disposed on a substrate. A longitudinal length of the nanowire is defined into a channel region of a first group III-N material, a source region electrically coupled with a first end of the channel region, and a drain region electrically coupled with a second end of the channel region. A second group III-N material on the first group III-N material serves as a charge inducing layer, and/or barrier layer on surfaces of nanowire. A gate insulator and/or gate conductor coaxially wraps completely around the nanowire within the channel region. Drain and source contacts may similarly coaxially wrap completely around the drain and source regions.

A semiconductor device having a novel buried junction architecture. The semiconductor device may have three terminals and a drift region between two of the terminals. The drift region includes an upper drift layer, a lower drift layer, and a buried junction layer between the upper and lower drift layers, wherein the upper and lower drift layers have a first type of doping. The buried junction layer comprises an interspersed pattern of a first material and a second material, the first material having a second type of doping opposite the first type of doping and the second material having the first type of doping and having a different doping concentration than the upper and lower drift layers.

A semiconductor structure, such as a group III nitride-based semiconductor structure is provided. The semiconductor structure includes a cavity containing semiconductor layer. The cavity containing semiconductor layer can have a thickness greater than two monolayers and a multiple cavities. The cavities can have a characteristic size of at least one nanometer and a characteristic separation of at least five nanometers.

Structures and formation methods of a semiconductor device structure are provided. The semiconductor device structure includes a supporting substrate. The semiconductor device structure also includes a first carrier-trapping layer covering the supporting substrate. The first carrier-trapping layer is doped with a group-IV dopant. The semiconductor device structure further includes an insulating layer covering the first carrier-trapping layer. In addition, the semiconductor device structure includes a semiconductor substrate over the insulating layer. The semiconductor device structure also includes a transistor. The transistor includes a gate stack over the semiconductor substrate and source and drain structures in the semiconductor substrate.

The present invention belongs to the field of semiconductor technology and relates to a polarization-doped enhancement mode HEMT device. The technical solution of the present invention grows the first barrier layer and the second barrier layer that contain gradient Al composition sequentially on the buffer layer. The gradient trends of the two layers are opposite. The three-dimensional electron gas (3DEG) and the three-dimensional hole gas (3DHG) are induced and generated in the barrier layers due to the inner polarization difference respectively. A trench insulated gate structure is at one side of the source which is away from the metal drain and is in contact with the source. First, since the highly concentrated electrons exist in the entire first barrier layer, the on-state current is improved greatly. Second, the vertical conductive channel between the source and the 3DEG are pinched off by the 3DHG, so as to realize the enhancement mode.

A semiconductor device may include a substrate, and spaced apart gate stacks on the substrate with adjacent gate stacks defining a respective trench therebetween, Each gate stack may include alternating layers of first and second semiconductor materials, with the layers of the second semiconductor material defining nanostructures. The semiconductor device may further include respective source/drain regions within the trenches, respective insulating regions adjacent lateral ends of the layers of the first semiconductor material, and respective conductive contact liners in the trenches.

A method for making semiconductor device may include forming spaced apart gate stacks on a substrate defining respective trenches therebetween. Each gate stack may include alternating layers of first and second semiconductor materials, with the layers of the second semiconductor material defining nanostructures. The method may further include forming respective source/drain regions within the trenches, forming respective insulating regions adjacent lateral ends of the layers of the first semiconductor material, and forming respective dopant blocking superlattices adjacent lateral ends of the nanostructures and offset outwardly from adjacent surfaces of the insulating regions. Each dopant blocking superlattice may include a plurality of stacked groups of layers, with each group of layers comprising stacked base semiconductor monolayers defining a base semiconductor portion, and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base semiconductor portions.

A method for making a semiconductor device may include forming spaced apart gate stacks on a substrate defining respective trenches therebetween. Each gate stack may include alternating layers of first and second semiconductor materials, with the layers of the second semiconductor material defining nanostructures. The method may further include forming respective source/drain regions within the trenches, forming respective insulating regions adjacent lateral ends of the layers of the first semiconductor material, and forming respective dopant blocking superlattices adjacent lateral ends of the nanostructures and flush with adjacent surfaces of the insulating regions. Each dopant blocking superlattice may include stacked groups of layers, with each group of layers including a plurality of stacked base semiconductor monolayers defining a base semiconductor portion, and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base semiconductor portions.

A method for making a semiconductor device may include forming spaced apart gate stacks on a substrate with adjacent gate stacks defining a respective trench therebetween. Each gate stack may include alternating layers of first and second semiconductor materials, with the layers of the second semiconductor material defining nanostructures. The method may further include forming respective source/drain regions within the trenches, respective insulating regions adjacent lateral ends of the layers of the first semiconductor material, and respective conductive contact liners in the trenches.