The present disclosure generally relates to integrated devices with a conductive barrier structure. In an example, a semiconductor device includes a substrate, a conductive barrier structure, a channel layer, a barrier layer, a gate, and a conductive structure. The substrate is of a first semiconductor material. The conductive barrier structure is on the substrate. The channel layer is of a second semiconductor material and is on the conductive barrier structure. The barrier layer is on the channel layer, and the channel layer is between the barrier layer and the conductive barrier structure. The gate is over the barrier layer opposing the channel layer. The conductive structure is electrically coupled between the conductive barrier structure, the channel layer, and the barrier layer.

A High electron mobility transistor (HEMT) includes a source electrode, a gate electrode, a drain electrode, a channel forming layer in which a two-dimensional electron gas (2DEG) channel is induced, and a channel supplying layer for inducing the 2DEG channel in the channel forming layer. The source electrode and the drain electrode are located on the channel supplying layer. A channel increase layer is between the channel supplying layer and the source and drain electrodes. A thickness of the channel supplying layer is less than about 15 nm.

Techniques are disclosed for forming transistor devices having reduced parasitic contact resistance relative to conventional devices. The techniques can be implemented, for example, using a standard contact stack such as a series of metals on, for example, silicon or silicon germanium (SiGe) source/drain regions. In accordance with one example such embodiment, an intermediate boron doped germanium layer is provided between the source/drain and contact metals to significantly reduce contact resistance. Numerous transistor configurations and suitable fabrication processes will be apparent in light of this disclosure, including both planar and non-planar transistor structures (e.g., FinFETs), as well as strained and unstrained channel structures. Graded buffering can be used to reduce misfit dislocation. The techniques are particularly well-suited for implementing p-type devices, but can be used for n-type devices if so desired.

A semiconductor device includes a buffer layer, a channel layer, a barrier layer, and agate electrode over a substrate, the gate electrode being disposed in a first opening with agate insulating film in between, the first opening running up to the middle of the channel layer through the barrier layer. The concentration of two-dimensional electron gas in a first region on either side of a second opening that will have a channel is controlled to be lower than the concentration of two-dimensional electron gas in a second region between an end of the first region and a source or drain electrode. The concentration of the two-dimensional electron gas in the first region is thus decreased, thereby the conduction band-raising effect of polarization charge is prevented from being reduced. This prevents a decrease in threshold potential, and thus improves normally-off operability.

A p-GaN high-electron-mobility transistor, includes a substrate, a channel layer stacked on the substrate, a supply layer stacked on the channel layer, a first doped layer stacked on the supply layer, a second doped layer stacked on the first doped layer, and a third doped layer stacked on the second doped layer. A doping concentration of the first doped layer and the doping concentration of the third doped layer are lower than a doping concentration of the second doped layer. A gate is located on the third doped layer, and a source and a drain are electrically connected to the channel layer and the supply layer, respectively.

A transistor device is provided that comprises a base structure, and a superlattice structure overlying the base structure and comprising a multichannel ridge having sloping sidewalls. The multichannel ridge comprises a plurality of heterostructures that each form a channel of the multichannel ridge, wherein a parameter of at least one of the heterostructures is varied relative to other heterostructures of the plurality of heterostructures. The transistor device further comprises a three-sided gate contact that wraps around and substantially surrounds the top and sides of the multichannel ridge along at least a portion of its depth.

A semiconductor device includes a buffer layer formed with a semiconductor adapted to produce piezoelectric polarization, and a channel layer stacked on the buffer layer, wherein a two-dimensional hole gas, generated in the channel layer by piezoelectric polarization of the buffer layer, is used as a carrier of the channel layer. On a complementary semiconductor device, the semiconductor device described above and an n-type field effect transistor are formed on the same compound semiconductor substrate. Also, a level shift circuit is manufactured by using the semiconductor device. Further, a semiconductor device manufacturing method includes forming a compound semiconductor base portion, forming a buffer layer on the base portion, forming a channel layer on the buffer layer, forming a gate on the channel layer, and forming a drain and source with the gate therebetween on the channel layer.

To provide a semiconductor wafer having a wafer, a compound semiconductor layer, a first insulating layer and a second insulating layer, wherein in the depth direction, oxygen atoms and nitrogen atoms are continuously distributed, the number of the nitrogen atoms along the depth direction shows its maximum in the first insulating layer, the total number of third atoms and fourth atoms along the depth direction becomes the largest in the compound semiconductor layer, the number of the oxygen atoms at the interface between the compound semiconductor layer and the first insulating layer is smaller than the number of the oxygen atoms at the interface between the first insulating layer and the second insulating layer.

According to one embodiment, a non-volatile memory device includes a plurality of electrodes, at least one semiconductor layer, conductive layers, and first and second insulating films. The electrodes are arranged side by side in a first direction. The semiconductor layer extends into the electrodes in the first direction. The conductive layers are provided between each electrode and the semiconductor layer and separated from each other in the first direction. The first insulating film contacts the conductive layers, and extends in the first direction along the semiconductor layer between the conductive layers and the semiconductor layer. The second insulating film is provided between the first insulating film and the semiconductor layer. The first insulating film includes a first portion located between the conductive layers and the second insulating film, and a second portion located between the interlayer insulating film and the second insulating film.

Techniques are disclosed for forming transistor devices having source and drain regions with high concentrations of boron doped germanium. In some embodiments, an in situ boron doped germanium, or alternatively, boron doped silicon germanium capped with a heavily boron doped germanium layer, are provided using selective epitaxial deposition in the source and drain regions and their corresponding tip regions. In some such cases, germanium concentration can be, for example, in excess of 50 atomic % and up to 100 atomic %, and the boron concentration can be, for instance, in excess of 1E20 cm.sup.3. A buffer providing graded germanium and/or boron concentrations can be used to better interface disparate layers. The concentration of boron doped in the germanium at the epi-metal interface effectively lowers parasitic resistance without degrading tip abruptness. The techniques can be embodied, for instance, in planar or non-planar transistor devices.