A stacked III-V semiconductor diode having an n.sup.+-layer with a dopant concentration of at least 10.sup.19 N/cm.sup.3, an n.sup.-layer with a dopant concentration of 10.sup.12-10.sup.16 N/cm.sup.3, a layer thickness of 10-300 microns, a p.sup.+-layer with a dopant concentration of 510.sup.18-510.sup.20 cm.sup.3, with a layer thickness greater than 2 microns, wherein said layers follow one another in the sequence mentioned, each comprising a GaAs compound. The n.sup.+-layer or the p.sup.+-layer is formed as the substrate and a lower side of the n.sup.-layer is materially bonded with an upper side of the n.sup.+-layer, and a doped intermediate layer is arranged between the n-layer and the p+-layer and materially bonded with an upper side and a lower side.

Techniques related to forming low defect density III-N films, device structures, and systems incorporating such films are discussed. Such techniques include epitaxially growing a first crystalline III-N structure within an opening of a first dielectric layer and extending onto the first dielectric layer, forming a second dielectric layer over the first dielectric layer and laterally adjacent to a portion of the first structure, and epitaxially growing a second crystalline III-N structure extending laterally onto a region of the second dielectric layer.

A semiconductor device includes a semiconductor member having a mesa structure in which a first semiconductor layer and a second semiconductor layer are laminated on each other and having a pn junction; an insulating film disposed on a side surface of the mesa structure and on an outside upper surface of the mesa structure; a first electrode connected to the second semiconductor layer on the upper surface of the mesa structure, and extends on the side surface of the mesa structure and on the outside upper surface of the mesa structure on the insulating film; and a second electrode connected to the first semiconductor layer on a lower surface of the first semiconductor layer, and having a capacitance of the insulating film when a reverse bias voltage is applied between the first electrode and the second electrode, so that a first voltage applied to the insulating film between a corner position (a first position) where the side surface of the insulating film disposed on the side surface of the mesa structure and the upper surface of the insulating film disposed on the outside upper surface of the mesa structure are connected to each other, and a corner position (a second position) where the side surface of the mesa structure and the outside upper surface of the mesa structure are connected to each other, is equal to or smaller than a second voltage applied to the first semiconductor layer between a pn junction interface (a third position) in a lower part of a region where the first electrode is in contact with the second semiconductor layer, and a position directly under the third position (a fourth position) at a height of the second position.

A circuit element is formed on a substrate made of a compound semiconductor. A bonding pad is disposed on the circuit element so as to at least partially overlap the circuit element. The bonding pad includes a first metal film and a second metal film formed on the first metal film. A metal material of the second metal film has a higher Young's modulus than a metal material of the first metal film.

A method comprises providing a substrate comprising an n-type Al/In/GaN semiconductor material. A surface of the substrate is dry-etched to form a trench therein and cause dry-etch damage to remain on the surface. The surface of the substrate is immersed in an electrolyte solution and illuminated with above bandgap light having a wavelength that generates electron-hole pairs in the n-type Al/In/GaN semiconductor material, thereby photoelectrochemically etching the surface to remove at least a portion of the dry-etch damage.

A switching device including a GaN substrate; an unintentionally doped GaN layer on a first surface of the GaN substrate; a regrown unintentionally doped GaN layer on the unintentionally doped GaN layer; a regrowth interface between the unintentionally doped GaN layer and the regrown unintentionally doped GaN layer; a p-GaN layer on the regrown unintentionally doped GaN layer; a first electrode on the p-GaN layer; and a second electrode on a second surface of the GaN substrate.

A technique that recovers from degradation in crystalline nature in an ion-implanted region is provided. A method of manufacturing a semiconductor device, includes: an ion implantation step of ion-implanting p-type impurities by a cumulative dose D into an n-type semiconductor layer containing n-type impurities; and a thermal annealing step of annealing an ion-implanted region of the n-type semiconductor layer where the p-type impurities are ion-implanted, in an atmosphere containing nitrogen, at a temperature T for a time t, wherein the cumulative dose D, the temperature T, and the time t satisfy a predetermined relationship.

There is provided a nitride semiconductor substrate, including: a substrate configured as an n-type semiconductor substrate; and a drift layer provided on the substrate and configured as a gallium nitride layer containing donors and carbons, wherein a concentration of the donors in the drift layer is 5.010.sup.6 / cm.sup.3 or less, and is equal to or more than a concentration of the carbons that function as acceptors in the drift layer, over an entire area of the drift layer, and a difference obtained by subtracting the concentration of the carbons that function as acceptors in the drift layer from the concentration of the donors in the drift layer, is gradually increased from a substrate side toward a surface side of the drift layer.

A semiconductor diode includes an engineered substrate including a substantially single crystal layer, a buffer layer coupled to the substantially single crystal layer, and a semi-insulating layer coupled to the buffer layer. The semiconductor diode also includes a first N-type gallium nitride layer coupled to the semi-insulating layer and a second N-type gallium nitride layer coupled to the first N-type gallium nitride layer. The first N-type gallium nitride layer has a first doping concentration and the second N-type gallium nitride layer has a second doping concentration less than the first doping concentration. The semiconductor diode further includes a P-type gallium nitride layer coupled to the second N-type gallium nitride layer, an anode contact coupled to the P-type gallium nitride layer, and a cathode contact coupled to a portion of the first N-type gallium nitride layer.

The present description concerns an electronic device comprising a stack of a Schottky diode and of a bipolar diode, connected in parallel by a first electrode located in a first cavity and a second electrode located in a second cavity.