An SiC semiconductor device has a p type region including a low concentration region and a high concentration region filled in a trench formed in a cell region. A p type column is provided by the low concentration region, and a p.sup.+ type deep layer is provided by the high concentration region. Thus, since a SJ structure can be made by the p type column and the n type column provided by the n type drift layer, an on-state resistance can be reduced. As a drain potential can be blocked by the p.sup.+ type deep layer, at turnoff, an electric field applied to the gate insulation film can be alleviated and thus breakage of the gate insulation film can be restricted. Therefore, the SiC semiconductor device can realize the reduction of the on-state resistance and the restriction of breakage of the gate insulation film.

An epitaxial structure for a high-electron-mobility transistor includes a substrate, a nucleation layer, a buffer layered unit, a channel layer, and a barrier layer sequentially stacked on one another in such order. The buffer layered unit includes a plurality of p-i-n heterojunction stacks. Each of the p-i-n heterojunction stacks includes p-type, i-type, and n-type layers which are made of materials respectively represented by chemical formulas of Al.sub.xGa.sub.(1-x)N, Al.sub.yGa.sub.(1-y)N, and Al.sub.zGa.sub.(1-z)N. For each of the p-i-n heterojunction stacks, x decreases and z increases along a direction away from the nucleation layer, and y is consistent and ranges from 0 to 0.7.

The present invention relates to the inspection process which includes providing access to the microdevice contacts, measuring the microdevice and analyzing the data to identify defects or performance of the micro device. The invention also relates to the forming of test electrodes on microdevices. The test electrodes may be connected to hidden contacts. The type of microdevices may be vertical, lateral or a flip chip.

A semiconductor device includes a superlattice layer, a high-resistance layer on the superlattice layer and doped with a first material and a second material different from the first material, a channel layer on the high-resistance layer, a barrier layer on the channel layer and including a material having an energy band gap different from that of the channel layer, a gate electrode on the barrier layer, a gate semiconductor layer between the barrier layer and the gate electrode, and a source electrode and a drain electrode positioned on respective sides of the gate electrode and connected to the channel layer. The high-resistance layer includes a first region in which a concentration of the second material is constant, and a second region, on the first region, in which a concentration of the second material decreases in a direction away from a lower surface of the high-resistance layer.

A semiconductor device having an isolation structure and a method of fabricating the same are disclosed. The method includes forming first and second superlattice structures on a substrate, forming a dielectric oxide layer on the first and second superlattice structures, forming a polysilicon layer on the dielectric oxide layer, forming a first isolation opening above the first and second superlattice structures, forming a second isolation opening between the first and second superlattice structures, and depositing a dielectric layer in the first and second isolation openings to form an isolation structure. Forming the first isolation opening includes forming a first metal oxide layer on a first portion of the dielectric oxide exposed during forming of the first isolation opening. Forming the second isolation opening includes forming a second metal oxide layer on a second portion of the dielectric oxide layer exposed during forming of the second isolation opening.

Various embodiments of the present disclosure are directed towards an integrated chip a semiconductor device including a plurality of superlattice layers disposed over a substrate. The plurality of superlattice layers include a first superlattice layer overlying a second superlattice layer. A channel layer overlies the plurality of superlattice layers. An active layer overlies the channel layer. A first interlayer buffer layer is disposed directly between the first superlattice layer and the second superlattice layer. The first interlayer buffer layer comprises a first density of dislocations greater than a second density of dislocations in the first superlattice layer.

A semiconductor gate-all-around (GAA) device may include a semiconductor substrate, source and drain regions on the semiconductor substrate, a plurality of semiconductor nanostructures extending between the source and drain regions, a gate surrounding the plurality of semiconductor nanostructures in a gate-all-around arrangement, and a dopant diffusion liner adjacent at least one of the source and drain regions and comprising a first superlattice. The first superlattice may include a plurality of stacked groups of layers, with each group of layers comprising 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.

In one embodiment, a transistor includes a substrate, a buffer layer on the substrate a channel layer on the buffer layer, and one or more polarization layers on the channel layer. The one or more polarization layers include a group III-N material comprising a first group III constituent and a second group III constituent. The transistor further includes a plurality of p-type doped layers on the one or more polarization layers. Each of the plurality of p-type doped layers includes a first p-type dopant and the III-N material, wherein each successive layer of the first p-type doped layers has a lower proportion of the first group III constituent to the second group III constituent relative to a layer below it. The transistor also includes a p-type doped layer on the plurality of p-type doped layers comprising a second p-type dopant and a group III-N material.

Provided are a nitride semiconductor buffer structure and a semiconductor device including the same. The buffer structure may include a plurality of buffer layers between a substrate and an active layer. The active layer may include a nitride semiconductor. The plurality of buffer layers may be stacked on each other on the substrate. Each of the plurality of buffer layers may have a super lattice structure and may include a doped nitride semiconductor. The plurality of buffer layers may have different compositions from each other. Adjacent buffer layers, among the plurality of buffer layers, may have different doping concentrations from each other.

A multilayered semiconductor diode device can include a substrate including silicon carbide (SiC) with an epitaxial drift layer including a first semiconductor oxide material above the SiC substrate with respect to a growth direction. The multilayered semiconductor diode device can further include a polar nitride layer including a polar semiconductor nitride material above the epitaxial drift layer with respect to the growth direction, and a metal layer above the polar nitride layer with respect to the growth direction.