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.

Embodiments of the invention include a method for fabricating a semiconductor device and the resulting structure. A substrate is provided. A plurality of metal portions are formed on the substrate, wherein the plurality of metal portions are arranged such that areas of the substrate remain exposed. A thin film layer is deposited on the plurality of metal portions and the exposed areas of the substrate. A dielectric layer is deposited, wherein the dielectric layer is in contact with portions of the thin film layer on the plurality of metal portions, and wherein the dielectric layer is not in contact with portions of the thin film layer on the exposed areas of the substrate such that one or more enclosed spaces are present between the thin film layer on the exposed areas of the substrate and the dielectric layer.

A High Electron Mobility Transistor (HEMT) and a method of forming the same are disclosed. The HEMT includes a first III-V compound layer having a first band gap and a second III-V compound layer having a second band gap over the first III-V compound layer, wherein the second band gap is greater than the first band gap. The HEMT further includes a first oxide layer over the second III-V compound layer; a first interfacial layer over the first oxide layer; and a passivation layer over the first interfacial layer.

There are disclosed herein various implementations of a semiconductor component including one or more aluminum silicon nitride layers. The semiconductor component includes a substrate, a group III-V intermediate body situated over the substrate, a group III-V buffer layer situated over the group III-V intermediate body, and a group III-V device fabricated over the group III-V buffer layer. The group III-V intermediate body includes the one or more aluminum silicon nitride layers.

A GaN-on-Si device structure and a method of fabrication are disclosed for improved die yield and device reliability of high current/high voltage lateral GaN transistors. A plurality of conventional GaN device structures comprising GaN epi-layers are fabricated on a silicon substrate (GaN-on-Si die). After processing of on-chip interconnect layers, a trench structure is defined around each die, through the GaN epi-layers and into the silicon substrate. A trench cladding is provided on proximal sidewalls, comprising at least one of a passivation layer and a conductive metal layer. The trench cladding extends over exposed surfaces of the GaN epi-layers, over the interface region with the substrate, and also over the exposed surfaces of the interconnect layers. This structure reduces risk of propagation of dicing damage and defects or cracks in the GaN epi-layers into active device regions. A metal trench cladding acts as a barrier for electro-migration of mobile ions.

A transistor device including a cap layer is described. One embodiment of such a device includes cap layer between a gate and a semiconductor layer. In one embodiment, the thickness of the cap layer is between 5 nm and 100 nm. In another embodiment, the cap layer can be doped, such as delta-doped or doped in a region remote from the semiconductor layer. Devices according to the present invention can show capacitances which are less drain bias dependent, resulting in improved linearity.

A circuit can include a transistor coupled to a resistor or a diode. In an embodiment, the circuit can include a pair of transistors arranged in a cascode configuration, and each of the transistors can have a corresponding component connected in parallel. In a particular embodiment, the components can be resistors, and in another particular, embodiment, the components can be diodes. The circuit can have less on-state resistance as compared to a circuit in which only one of the components is used, and reduces the off-state voltage on the gate of a high-side transistor. An integrated circuit can include a high electron mobility transistor structure and a resistor, a diode, a pair of resistors, or a pair of diodes.

A semiconductor device with a substrate, a low defect layer formed in a fixed position relative to the substrate, and a barrier layer comprising III-N semiconductor material formed on the low-defect layer and forming an electron gas in the low-defect layer. The device also has a source contact, a drain contact, and a gate contact for receiving a potential, the potential for adjusting a conductive path in the electron gas and between the source contact and the drain contact. Lastly, the device has a one-sided PN junction between the barrier layer and the substrate.

Methods of forming a graphene nanopattern, graphene-containing devices, and methods of manufacturing the graphene-containing devices are provided. A method of forming the graphene nanopattern may include forming a graphene layer on a substrate, forming a block copolymer layer on the graphene layer and a region of the substrate exposed on at least one side of the graphene layer, forming a mask pattern from the block copolymer layer by removing one of a plurality of first region and a plurality of second regions of the block copolymer, and patterning the graphene layer in a nanoscale by using the mask pattern as an etching mask. The block copolymer layer may be formed to directly contact the graphene layer. The block copolymer layer may be formed to directly contact a region of the substrate structure that is exposed on at least one side of the graphene layer.

Provided is a stabilizing circuit structure using a sense field effect transistor (sense-FET). A power semiconductor module includes a depletion-mode field effect transistor (D-mode FET) and the sense FET that has same structure as the D-mode FET and varies in area. Also the power semiconductor module includes not only an enhancement-mode field effect transistor (E-mode FET), but also the stabilizing circuit including circuit elements such as a resistor, a capacitor, an inductor, or a diode.