A nitride semiconductor device includes an electron transit layer (103) that is formed of a nitride semiconductor, an electron supply layer (104) that is formed on the electron transit layer (103), that is formed of a nitride semiconductor whose composition is different from the electron transit layer (103) and that has a recess (109) which reaches the electron transit layer (103) from a surface, a thermal oxide film (111) that is formed on the surface of the electron transit layer (103) exposed within the recess (109), a gate insulating film (110) that is embedded within the recess (109) so as to be in contact with the thermal oxide film (111), a gate electrode (108) that is formed on the gate insulating film (110) and that is opposite to the electron transit layer (103) across the thermal oxide film (111) and the gate insulating film (110), and a source electrode (106) and a drain electrode (107) that are provided on the electron supply layer (104) at an interval such that the gate electrode (108) intervenes therebetween.

A field effect transistor includes: a semiconductor region including a first inactive region, an active region, and a second inactive region arranged side by side in a first direction; a gate electrode, a source electrode, and a drain electrode on the active region; a gate pad on the first inactive region; a gate guard on and in contact with the semiconductor region, the gate guard being apart from the gate pad and located between an edge on the first inactive region side of the semiconductor region and the gate pad; a drain pad on the second inactive region; a drain guard on and in contact with the semiconductor region, the drain guard being apart from the drain pad and located between an edge on the second inactive region side of the semiconductor region and the drain pad; and a metal film electrically connected to the gate guard.

The present invention relates to: a method for manufacturing a GaN-based power device, the method comprising a step of irradiating particle beams onto a silicon substrate of a GaN-based power device, in which the silicon substrate is included; and a GaN-based power device manufactured by the method for manufacturing a GaN-based power device.

A semiconductor device with favorable electrical characteristics is provided. A semiconductor device with stable electrical characteristics is provided. The semiconductor device includes a semiconductor layer, a first insulating layer, and a first conductive layer. The first insulating layer is provided over the semiconductor layer. The first conductive layer is provided over the first insulating layer. The semiconductor layer includes a first region that overlaps with the first conductive layer and the first insulating layer, a second region that does not overlap with the first conductive layer and overlaps with the first insulating layer, and a third region that overlaps with neither the first conductive layer nor the first insulating layer. The semiconductor layer contains a metal oxide. The second region and the third region contain a first element. The first element is one or more elements selected from boron, phosphorus, aluminum, and magnesium. The first element exists in a state of being bonded to oxygen.

In some examples, a transistor comprises a gallium nitride (GaN) layer; a GaN-based alloy layer having a top side and disposed on the GaN layer, wherein source, drain, and gate contact structures are supported by the GaN layer; and a first doped region positioned in a drain access region and extending from the top side into the GaN layer.

A method for fabricating high electron mobility transistor (HEMT) includes the steps of: forming a buffer layer on a substrate; forming a barrier layer on the buffer layer; forming a hard mask on the barrier layer; performing an implantation process through the hard mask to form a doped region in the barrier layer and the buffer layer; removing the hard mask and the barrier layer to form a first trench; forming a gate dielectric layer on the hard mask and into the first trench; forming a gate electrode on the gate dielectric layer; and forming a source electrode and a drain electrode adjacent to two sides of the gate electrode.

A semiconductor device includes a doped substrate, a barrier layer, a channel layer, and a doped semiconductor structure. The barrier layer is disposed on the doped substrate. The channel layer is disposed between the doped substrate and the barrier layer, in which a bandgap of the barrier layer is greater than a bandgap of the channel layer. The doped semiconductor structure is embedded in the doped substrate and at a position lower than the channel layer, in which the doped substrate and the doped semiconductor structure have different polarities, so as to form a diode therebetween.

A semiconductor device includes a doped substrate, a barrier layer, a channel layer, a doped semiconductor structure, and the conductive structure. The barrier layer is disposed on the doped substrate. The channel layer is disposed between the doped substrate and the barrier layer, in which a bandgap of the barrier layer is greater than a bandgap of the channel layer. The doped semiconductor structure is embedded in the doped substrate, in which the doped substrate and the doped semiconductor structure have different polarities, so as to form a diode therebetween. The conductive structure is disposed over the doped substrate and makes contact with the doped semiconductor structure, in which the conductive structure extends from the doped semiconductor structure to a position higher than the channel layer and the barrier layer.

Devices, systems, methods, computer-implemented methods, apparatus, and/or computer program products that can facilitate a suspended Majorana fermion device comprising an ion implant defined nanorod in a semiconducting device are provided. According to an embodiment, a quantum computing device can comprise a Majorana fermion device coupled to an ion implanted region. The quantum computing device can further comprise an encapsulation film coupled to the ion implanted region and a substrate layer. The encapsulation film suspends the Majorana fermion device in the quantum computing device.

A method includes depositing a first epitaxial layer of an aluminum gallium nitride (AlGaN) material onto a preliminary substrate and polishing the first layer's surface. Ions are implanted beneath the surface, which is bonded to a seed insulating substrate. Annealing is performed, resulting in second epitaxial layer on preliminary substrate and third epitaxial layer on seed insulating substrate. Third layer's surface is polished to obtain a seed wafer. In some implementations, a fourth epitaxial layer of a second AlGaN material is deposited onto surface of third layer. Fourth layer's surface is polished, and ions are implanted beneath the surface, which is bonded to a product insulating substrate. Annealing is performed, resulting in fifth epitaxial layer on seed insulating substrate and sixth epitaxial layer on product insulating substrate. The sixth layer can be used to obtain an AlGaN product, and the fifth layer can be reused to fabricate additional AlGaN products.