A semiconductor device includes; a substrate including a first region and a second region, a first active pattern extending upward from the first region, a first superlattice pattern on the first active pattern, a first active fin centrally disposed on the first active pattern, a first gate electrode disposed on the first active fin, and first source/drain patterns disposed on opposing sides of the first active fin and on the first active pattern. The first superlattice pattern includes at least one first semiconductor layer and at least one first blocker-containing layer, and the first blocker-containing layer includes at least one of oxygen, carbon, fluorine and nitrogen.

A method includes forming a silicon substrate including first and second substrate layers, the first substrate layer extending to the rear surface, the second substrate layer extending to a first side of the silicon substrate that is opposite from the rear surface such that the first substrate layer is completely separated from the first side by the second substrate layer, forming a nucleation region on the first side of the silicon substrate, the nucleation region including a nitride layer, forming a lattice transition layer on the nucleation region, the lattice transition layer being configured to alleviate stress arising in the silicon substrate due to lattice mismatch between the silicon substrate and other layers in the compound semiconductor device structure, and epitaxially growing a type III-V semiconductor nitride region on the lattice transition layer.

Devices and methods for switch body connections to achieve soft breakdown. In some embodiments, a method of implementing a radio-frequency switching device can include providing an assembly of source, gate, and drain implemented on an active region; providing a first body contact implemented at a first end of the assembly; and providing a second body contact implemented at a second end of the assembly, the second end distal from the first end along a width of the radio-frequency switching device.

Provided are a semiconductor substrate and a transistor. The semiconductor substrate includes a base, an insulating layer, a semiconductor layer, a wide bandgap diffusion buffer layer and a nucleation layer. The insulating layer is disposed on the base. The semiconductor layer is disposed on the insulating layer. The wide bandgap diffusion buffer layer is disposed on the semiconductor layer, wherein the bandgap of the wide bandgap buffer diffusion layer is higher than 2.5 eV. The nucleation layer is disposed on the wide bandgap diffusion buffer layer, wherein the nucleation layer includes an aluminum-containing layer.

A field-effect transistor includes a substrate having conductivity and made of gallium nitride, a buffer layer provided on the substrate and made of C-doped GaN, a drift layer provided on the buffer layer and made of undoped GaN, and a channel layer provided on the drift layer, made of undoped AlGaN, and joined to the drift layer by heterojunction. A gate electrode is provided on the channel layer. A source electrode and a drain electrode are each provided in regions on both sides of the gate electrode on the channel layer.

Described herein are lateral III-N (e.g., GaN) devices having a III-N depleting layer. A circuit includes a depletion-mode transistor with a source connected to a drain of an enhancement-mode transistor. The gate of the depletion-mode transistor and the gate of the enhancement-mode transistor are biased at zero volts, and the drain of the depletion-mode transistor is biased at positive voltage to block a current in a forward direction. Then, the bias of the gate of the enhancement-mode transistor is changed to a first voltage greater than the threshold voltage of the enhancement-mode transistor and a first current is allowed to flow through the channel in a forward direction. Then, the bias of the gate of the depletion-mode transistor is changed to a second voltage and a second current is allowed to flow through the channel in a forward direction where the second current is greater than the first current.

A microelectronic device includes a substrate, at least two doped well regions, an epitaxial structure, and at least two power elements. The doped well regions are disposed in the substrate, and are spaced apart from each other. Each of the doped well regions has a doping type opposite to that of the substrate. The epitaxial structure is disposed on the substrate, and is in contact with the doped well regions. The power elements are disposed on the epitaxial structure opposite to the substrate, and are cascade connected with each other. A low potential terminal of each of the power elements is electrically connected to a respective one of the doped well regions. A method for making the microelectronic device is also provided.

Semiconductor structures and methods of forming semiconductor structures that inhibit the conductivity of parasitic channels are described. In one example, a semiconductor structure includes a semiconductor substrate and a III-nitride material region over a top surface of the semiconductor substrate. The semiconductor substrate includes a bulk region below the top surface and a parasitic channel that extends to a depth from the top surface toward the bulk region of the semiconductor substrate. The parasitic channel comprises a first region and a second region. The first region of the parasitic channel comprises an implanted species having a relative atomic mass of less than 5, and the second region of the parasitic channel is free from the implanted species or the implanted species is present in the second region at a concentration that is less than in the first region.

A semiconductor device includes a transistor, a semiconductor layer, an active region and a conductive layer. The active region is in the semiconductor layer. The conductive layer is configured to maintain a channel in the active region when the transistor is triggered to be conducted.

Some embodiments of the disclosure provide a method for forming a semiconductor device. The method includes: forming a plurality of semiconductor material layers on a doped substrate; removing a part of the plurality of semiconductor material layers to form an exposed doped substrate; and ion implanting a dopant into the exposed doped substrate to form a doped semiconductor structure, where the doped substrate and the doped semiconductor structure have different polarities.