Abstract: Production of an integrated circuit including an electrical contact on SiC is disclosed. One embodiment provides for production of an electrical contact on an SiC substrate, in which a conductive contact is produced on a boundary surface of the SiC substrate by irradiation and absorption of a laser pulse on an SiC substrate.

Abstract: A target made of a metal material is sputtered to form a metal film on a silicon carbide wafer. At this time, the metal film is formed under a condition that an incident energy of incidence, on the silicon carbide wafer, of the metal material sputtered from the target and a sputtering gas flowed in through a gas inlet port is lower than a binding energy of silicon carbide, and more specifically lower than 4.8 eV. For example, the metal film is formed while a high-frequency voltage applied between a cathode and an anode is set to be equal to or higher than 20V and equal to or lower than 300V.

Abstract: A method for fabricating a Schottky device includes the following sequences. First, a substrate with a first conductivity type is provided and an epitaxial layer with the first conductivity type is grown on the substrate. Then, a patterned dielectric layer is formed on the epitaxial layer, and a metal silicide layer is formed on a surface of the epitaxial layer. A dopant source layer with a second conductivity type is formed on the metal silicide layer, followed by applying a thermal drive-in process to diffuse the dopants inside the dopant source layer into the epitaxial layer. Finally, a conductive layer is formed on the metal silicide layer.

Abstract: Disclosed are structures and methods related to metallization of a doped gallium arsenide (GaAs) layer. In some embodiments, such metallization can include a tantalum nitride (TaN) layer formed on the doped GaAs layer, and a metal layer formed on the TaN layer. Such a combination can yield a Schottky diode having a low turn-on voltage, with the metal layer acting as an anode and an electrical contact connected to the doped GaAs layer acting as a cathode. Such a Schottky diode can be utilized in applications such as radio-frequency (RF) power detection, reference-voltage generation using a clamp diode, and photoelectric conversion. In some embodiments, the low turn-on Schottky diode can be fabricated utilizing heterojunction bipolar transistor (HBT) processes.

Abstract: Disclosed herein is a nitride based semiconductor device. There is provided a nitride based semiconductor device including a base substrate; a semiconductor layer disposed on the base substrate; and an electrode structure disposed on the semiconductor layer, wherein the electrode structure includes: a first electrode ohmic-contacting the semiconductor layer; a ohmic contact unit ohmic-contacting the semiconductor layer and spaced apart from the first electrode; and a schottky contact unit schottky-contacting the semiconductor layer and covering the ohmic contact unit.

Abstract: Production of an integrated circuit including an electrical contact on SiC is disclosed. One embodiment provides for production of an electrical contact on an SiC substrate, in which a conductive contact is produced on a boundary surface of the SiC substrate by irradiation and absorption of a laser pulse on an SiC substrate.

Abstract: A method of making a diode begins by depositing an AlxGa1-xN nucleation layer on a SiC substrate, then depositing an n+ GaN buffer layer, an n? GaN layer, an AlxGa1-xN barrier layer, and an SiO2 dielectric layer. A portion of the dielectric layer is removed and a Schottky metal deposited in the void. The dielectric layer is affixed to the support layer with a metal bonding layer using an Au—Sn utectic wafer bonding process, the substrate is removed using reactive ion etching to expose the n+ layer, selected portions of the n+, n?, and barrier layers are removed to form a mesa diode structure on the dielectric layer over the Schottky metal; and an ohmic contact is deposited on the n+ layer.

Abstract: Disclosed herein is a nitride based semiconductor device. There is provided a nitride based semiconductor device including: a base substrate; an epitaxial growth layer disposed on the base substrate and generating 2-dimensional electron gas (2DEG) therein; and an electrode structure disposed on the epitaxial growth layer and having an extension extending into the epitaxial growth layer, wherein the epitaxial growth layer includes a depressing part depressed thereinto from the surface of the epitaxial growth layer, and the depressing part includes: a first area in which the extension is disposed; and a second area that is an area other than the first area.

Abstract: A vertical conduction nitride-based Schottky diode is formed using an insulating substrate which was lifted off after the diode device is encapsulated on the front side with a wafer level molding compound. The wafer level molding compound provides structural support on the front side of the diode device to allow the insulating substrate to be lifted off so that a conductive layer can be formed on the backside of the diode device as the cathode electrode. A vertical conduction nitride-based Schottky diode is thus realized. In another embodiment, a protection circuit for a vertical GaN Schottky diode employs a silicon-based vertical PN junction diode connected in parallel to the GaN Schottky diode to divert reverse bias avalanche current.

Abstract: A schottky diode includes a SiC substrate which has a first surface and a second surface facing away from the first surface, a semiconductor layer which is formed on the first surface of the SiC substrate, a schottky electrode which is in contact with the semiconductor layer, and an ohmic electrode which is in contact with the second surface of the SiC substrate. The first surface of the SiC substrate is a (000-1) C surface, upon which the semiconductor layer is formed.

Abstract: The present invention provides a silicon carbide Schottky-barrier diode device and a method for manufacturing the same. The silicon carbide Schottky bather diode device includes a primary n? epitaxial layer, an n+ epitaxial region, and a Schottky metal layer. The primary n? epitaxial layer is deposited on an n+ substrate joined with an ohmic metal layer at an undersurface thereof. The n+ epitaxial region is formed by implanting n+ ions into a central region of the primary n? epitaxial layer. The Schottky metal layer is deposited on the n+ epitaxial layer.

Abstract: A method for forming a gallium nitride based semiconductor diode includes forming Schottky contacts on the upper surface of mesas formed in a semiconductor body formed on a substrate. Ohmic contacts are formed on the lower surface of the semiconductor body. In one embodiment, an insulating layer is formed over the Schottky and ohmic contacts and vias are formed in the insulating layer to the Schottky and ohmic contacts to form the anode and cathode electrodes. In another embodiment, vias are formed in the insulating layer to the Schottky contacts and vias are formed in the semiconductor body to the ohmic contacts. An anode electrode is formed in electrical contact with the Schottky contacts. A cathode electrode is formed in electrical contact with the ohmic contacts on the backside of the substrate.

Abstract: According to one embodiment, an electronic device includes a side wall, an interface component, a partition wall, and a protrusion. The side wall is formed on one of the bottom wall and the top wall of a housing to spatially separate the inside of the housing from the outside. The side wall includes a through opening. The interface component faces the through opening in the housing. The partition wall is formed on the one of the bottom wall and the top wall and coupled perpendicularly to the side wall. The partition wall spatially separates the inside of the housing and a component retainer formed as a cutout or a recess of the housing. The protrusion is formed on the one of the bottom wall and the top wall to be spaced apart from the partition wall. The interface component is held between the partition wall and the protrusion.

Abstract: A silicon carbide semiconductor device with a Schottky barrier diode includes a first conductivity type silicon carbide substrate, a first conductivity type silicon carbide drift layer on a first surface of the substrate, a Schottky electrode forming a Schottky contact with the drift layer, and an ohmic electrode on a second surface of the substrate. The Schottky electrode includes an oxide layer in direct contact with the drift layer. The oxide layer is made of an oxide of molybdenum, titanium, nickel, or an alloy of at least two of these elements.

Abstract: The present invention relates to the field of microelectronic technology. It discloses a mixed Schottky/P-N junction diode and a method of making the same. The mixed Schottky/P-N junction diode comprises a semiconductor substrate having a bulk region and a doped region, and a conductive layer on the semiconductor substrate. The doped region has opposite doping from that of the bulk region. A P-N junction is formed between the bulk region and the doped region, a Schottky junction is formed between the conductive layer and the semiconductor substrate, and an ohmic contact is formed between the conductive layer and the doped region. The mixed Schottky/P-N junction diode of the present invention has high operating current, fast switching speed, small leakage current, high breakdown voltage, ease of fabrication and other advantages.

Abstract: Hardmask films having high hardness and low stress are provided. In some embodiments a film has a stress of between about ?600 MPa and 600 MPa and hardness of at least about 12 GPa. In some embodiments, a hardmask film is prepared by depositing multiple sub-layers of doped or undoped silicon carbide using multiple densifying plasma post-treatments in a PECVD process chamber. In some embodiments, a hardmask film includes a high-hardness boron-containing film selected from the group consisting of SixByCz, SixByNz, SixByCzNw, BxCy, and BxNy. In some embodiments, a hardmask film includes a germanium-rich GeNx material comprising at least about 60 atomic % of germanium. These hardmasks can be used in a number of back-end and front-end processing schemes in integrated circuit fabrication.

Abstract: In an MIS-type GaN-FET, a base layer made of a conductive nitride including no oxygen, here, TaN, is provided on a surface layer as a nitride semiconductor layer to cover at least an area of a lower face of a gate insulation film made of Ta2O5 under a gate electrode.

Abstract: One embodiment of depositing a gallium nitride (GaN) film on a substrate comprises providing a source of indium (In) and gallium (Ga) and depositing a monolayer of indium (In) on the surface of the gallium nitride (GaN) film. The monolayer of indium (In) acts as a surfactant to modify the surface energy and facilitate the epitaxial growth of the film by suppressing three dimensional growth and enhancing or facilitating two dimensional growth. The deposition temperature is kept sufficiently high to enable the indium (In) to undergo absorption and desorption on the gallium nitride (GaN) film without being incorporated into the solid phase gallium nitride (GaN) film. The gallium (Ga) and indium (In) can be provided by a single source or separate sources.

Abstract: This invention discloses bottom-anode Schottky (BAS) device supported on a semiconductor substrate having a bottom surface functioning as an anode electrode with an epitaxial layer has a same doped conductivity as said anode electrode overlying the anode electrode. The BAS device further includes an Schottky contact metal disposed in a plurality of trenches and covering a top surface of the semiconductor substrate between the trenches. The BAS device further includes a plurality of doped JBS regions disposed on sidewalls and below a bottom surface of the trenches doped with an opposite conductivity type from the anode electrode constituting a junction barrier Schottky (JBS) with the epitaxial layer disposed between the plurality of doped JBS regions. The BAS device further includes an ultra-shallow Shannon implant layer disposed immediate below the Schottky contact metal in the epitaxial layer between the plurality of doped JBS regions.

Abstract: A composition and method for formation of ohmic contacts on a semiconductor structure are provided. The composition includes a TiAlxNy material at least partially contiguous with the semiconductor structure. The TiAlxNy material can be TiAl3. The composition can include an aluminum material, the aluminum material being contiguous to at least part of the TiAlxNy material, such that the TiAlxNy material is between the aluminum material and the semiconductor structure. The method includes annealing the composition to form an ohmic contact on the semiconductor structure.

Abstract: The present invention relates a method for forming a monocrystalline GeN layer (4) on a substrate (1) comprising at least a Ge surface (3). The method comprises, while heating the substrate (1) to a temperature between 550° C. and 940° C., exposing the substrate (1) to a nitrogen gas flow. The present invention furthermore provides a structure comprising a monocrystalline GeN layer (4) on a substrate (1). The monocrystalline GeN formed by the method according to embodiments of the invention allows passivation of surface states present at the Ge surface (3).

Abstract: A schottky diode includes a SiC substrate which has a first surface and a second surface facing away from the first surface, a semiconductor layer which is formed on the first surface of the SiC substrate, a schottky electrode which is in contact with the semiconductor layer, and an ohmic electrode which is in contact with the second surface of the SiC substrate. The first surface of the SiC substrate is a (000-1) C surface, upon which the semiconductor layer is formed.

Abstract: A wide bandgap semiconductor device with surge current protection and a method of making the device are described. The device comprises a low doped n-type region formed by plasma etching through the first epitaxial layer grown on a heavily doped n-type substrate and a plurality of heavily doped p-type regions formed by plasma etching through the second epitaxial layer grown on the first epitaxial layer. Ohmic contacts are formed on p-type regions and on the backside of the n-type substrate. Schottky contacts are formed on the top surface of the n-type region. At normal operating conditions, the current in the device flows through the Schottky contacts. The device, however, is capable of withstanding extremely high current densities due to conductivity modulation caused by minority carrier injection from p-type regions.

Abstract: A method for manufacturing a Schottky barrier diode includes the following steps. First, a GaN substrate is prepared. A GaN layer is formed on the GaN substrate. A Schottky electrode including a first layer made of Ni or Ni alloy and in contact with the GaN layer is formed. The step of forming the Schottky electrode includes a step of forming a metal layer to serve as the Schottky electrode and a step of heat treating the metal layer. A region of the GaN layer in contact with the Schottky electrode has a dislocation density of 1×108 cm?2 or less.

Abstract: Some exemplary embodiments of a semiconductor device using a III-nitride heterojunction and a novel Schottky structure and related method resulting in such a semiconductor device, suitable for high voltage circuit designs, have been disclosed. One exemplary structure comprises a first layer comprising a first III-nitride material, a second layer comprising a second III-nitride material forming a heterojunction with said first layer to generate a two dimensional electron gas (2DEG) within said first layer, an anode comprising at least a first metal section forming a Schottky contact on a surface of said second layer, a cathode forming an ohmic contact on said surface of said second layer, a field dielectric layer on said surface of said second layer for isolating said anode and said cathode, and an insulating material on said surface of said second layer and in contact with said anode.

Abstract: Methods and apparatus are described for semiconductor devices. A method comprises providing a partially completed semiconductor device including a substrate, a semiconductor on the substrate, and a passivation layer on the semiconductor, and using a first mask, locally etching the passivation layer to expose a portion of the semiconductor, and without removing the first mask, forming a Schottky contact of a first material on the exposed portion of the semiconductor, then removing the first mask, and using a further mask, forming a step-gate conductor of a second material electrically coupled to the Schottky contact and overlying parts of the passivation layer adjacent to the Schottky contact. By minimizing the process steps between opening the Schottky contact window in the passivation layer and forming the Schottky contact material in this window, the gate leakage of a resulting field effect device having a Schottky gate may be substantially reduced.

Abstract: A method for manufacturing a metal-semiconductor contact in semiconductor Components is disclosed. There is a relatively high risk of contamination in the course of metal depositions in prior-art methods. In the disclosed method, the actual metal -semiconductor or Schottky contact is produced only after the application of a protective layer system, as a result of which it is possible to use any metals, particularly platinum, without the risk of contamination.

Abstract: Edge termination for silicon carbide devices has a plurality of concentric floating guard rings in a silicon carbide layer that are adjacent and spaced apart from a silicon carbide-based semiconductor junction. An insulating layer, such as an oxide, is provided on the floating guard rings and a silicon carbide surface charge compensation region is provided between the floating guard rings and is adjacent the insulating layer. Methods of fabricating such edge termination are also provided.

Abstract: Provided is an epitaxial substrate for semiconductor device that is capable of achieving a semiconductor device having high reliability in reverse characteristics of schottky junction. An epitaxial substrate for semiconductor device obtained by forming, on a base substrate, a group of group III nitride layers by lamination such that a (0001) crystal plane of each layer is approximately parallel to a substrate surface includes: a channel layer formed of a first group III nitride having a composition of Inx1Aly1Gaz1N (x1+y1+z1=1, z1>0); and a barrier layer formed of a second group III nitride having a composition of Inx2Aly2N (x2+y2=1, x2>0, y2>0), wherein the second group III nitride is a short-range-ordered mixed crystal having a short-range order parameter ? satisfying a range where 0???1.

Abstract: A method for manufacturing surgical blades from either a crystalline or poly-crystalline material, preferably in the form of a wafer, is disclosed. The method includes preparing the crystalline or poly-crystalline wafers by mounting them and machining trenches into the wafers. The methods for machining the trenches, which form the bevel blade surfaces, include a diamond blade saw, laser system, ultrasonic machine, and a hot forge press. The wafers are then placed in an etchant solution which isotropically etches the wafers in a uniform manner, such that layers of crystalline or poly-crystalline material are removed uniformly, producing single or double bevel blades. Nearly any angle can be machined into the wafer which remains after etching. The resulting radii of the blade edges is 5-500 nm, which is the same caliber as a diamond edged blade, but manufactured at a fraction of the cost.

Abstract: A method for producing a circuit board, the method includes the steps of: forming a lower wiring pattern on a substrate; forming an insulating film on the substrate to cover the lower wiring pattern; forming an opening in the insulating film to expose the lower wiring pattern; forming an upper wiring pattern on the insulating film; and forming an interconnect material pattern on a sidewall of the opening in the insulating film for connecting the lower wiring pattern and the upper wiring pattern.

Abstract: A semiconductor device includes: a nitride semiconductor layer including a channel layer, a Schottky electrode that contacts the nitride semiconductor layer and contains indium, and an ohmic electrode that contacts the channel layer. The nitride semiconductor layer includes a layer that contacts the Schottky electrode and contains AlGaN, InAlGaN or GaN. The Schottky electrode that contains indium includes one of an indium oxide layer and an indium tin oxide layer.

Abstract: A group III-nitride semiconductor Schottky diode comprises a conducting substrate having a first surface, a stack of multiple layers including a buffer layer and a semiconductor layer sequentially formed on the first surface, wherein the semiconductor layer comprises a group III nitride compound, a first electrode on the semiconductor layer, and a second electrode formed in contact with the first surface at a position adjacent to the stack of multiple layers. In other embodiments, the application also describes a method of fabricating the group III-nitride semiconductor Schottky diode.

Abstract: A method is provided for fabricating a thin film semiconductor device. The method includes providing a plurality of raw semiconductor materials. The raw semiconductor materials undergo a pre-reacting process to form a homogeneous compound semiconductor target material. The compound semiconductor target material is deposited onto a substrate to form a thin film having a composition substantially the same as a composition of the compound semiconductor target material.

Abstract: Edge termination for silicon carbide devices has a plurality of concentric floating guard rings in a silicon carbide layer that are adjacent and spaced apart from a silicon carbide-based semiconductor junction. An insulating layer, such as an oxide, is provided on the floating guard rings and a silicon carbide surface charge compensation region is provided between the floating guard rings and is adjacent the insulating layer. Methods of fabricating such edge termination are also provided.

Abstract: An SiC semiconductor device is provided, which comprises: a substrate made of silicon carbide and having a principal surface; a drift layer made of silicon carbide and disposed on the principal surface; an insulating layer disposed on the drift layer and including an opening; a Schottky electrode contacting with the drift layer through the opening; a termination structure disposed around an outer periphery of the opening; and second conductivity type layers disposed in a surface part of the drift layer, contacting the Schottky electrode, surrounded by the termination structure, and separated from one another. The second conductivity type layers include a center member and ring members. Each ring member surrounds the center member and is arranged substantially in a point symmetric manner with respect to the center member.

Abstract: Fabrication of a Schottky diodes may include providing a Schottky contact layer containing a low barrier metal layer with spaced apart high barrier metal islands therein on a first surface of a substrate. A diode contact is formed on a second surface of the substrate that is opposite to the first surface. Formation of the Schottky contact layer may include providing a liquid mixture of a high barrier metal and a low barrier metal on the first surface of the substrate. Temperature and/or relative concentrations of the high and low barrier metals in the liquid mixture may be controlled to cause regions of the high barrier metal to solidify within the liquid mixture and agglomerate to form the spaced apart high barrier metal islands while inhibiting solidification of the low barrier metal. The temperature and relative concentrations may then be controlled to cause the low barrier metal to solidify and form the low barrier metal layer containing the high barrier metal islands.

Abstract: Disclosed herein are a structure of a metal oxide semiconductor pseudomorphic high electron mobility transistor (MOS-PHEMT) suitable for use in a semiconductor device, such as a single-pole-double-throw (SPDT) switch of a monolithic microwave integrated circuit (MMIC); and a method of producing the same. The MOS-PHEMT structure is characterized in having a gate dielectric layer formed by atomic deposition from a gate dielectric selected from the group consisting of Al2O3, HfO2, La2O3, and ZrO2, and thereby rendering the semiconductor structure comprising the same, such as a high frequency switch device, to have less DC power loss, less insertion loss and better isolation.

Abstract: A silicon carbide semiconductor device provided as a semiconductor chip includes a substrate, a drift layer on the substrate, an insulation film on the drift layer, a semiconductor element formed in a cell region of the drift layer, a surface electrode formed on the drift layer and electrically coupled to the semiconductor element through an opening of the insulation film, and a passivation film formed above the drift layer around the periphery of the cell region to cover an outer edge of the surface electrode. The passivation film has an opening through which the surface electrode is exposed outside. A surface of the passivation film is made uneven to increase a length from an inner edge of the opening of the passivation film to a chip edge measured along the surface of the passivation film.

Abstract: Metallization contact structures and methods for forming a multiple-layer electrode structure on solar cells include depositing a conductive contact layer on a semiconductor substrate and depositing a metal bearing ink onto a portion of the conductive contact layer, wherein exposed portions of the conductive contact layer are adjacent to the metal bearing ink. The conductive contact layer is patterned by removing exposed portions of the conductive contact layer from the semiconductor substrate. The metal bearing ink is aligned with openings in a dielectric layer of the semiconductor substrate and with unexposed portions of the conductive contact layer. The unexposed portions of the conductive contact layer are interposed between the metal bearing ink and the dielectric layer such that the conductive contact layer pattern is aligned with metal bearing ink. The semiconductor substrate is thermally processed to form a current carrying metal gridline by sintering the metal bearing ink.

Abstract: A method is disclosed for preparing a surface of a Group III-Group V compound semiconductor for epitaxial deposition. The III-V semiconductor surface is treated with boron (B) at a temperature of between about 250° C. and about 350° C. A suitable form for supplying B for the surface treatment is diborane. The B treatment can be followed by epitaxial growth, for instance by a Group IV semiconductor, at temperatures similar to those of the B treatment. The method yields high quality heterojunction, suitable for fabricating a large variety of device structures.

Abstract: Pile ups of threading dislocations in thick graded buffer layer are reduced by enhancing dislocation gliding. During formation of a graded SiGe buffer layer, deposition of SiGe from a silicon precursor and a germanium precursor is interrupted one or more times with periods in which the flow of the silicon precursor to the substrate is stopped while the flow of the germanium precursor to the substrate is maintained.

Abstract: A semiconducting structure includes a thinned silicon substrate (110), a silicide layer (120) over the thinned silicon substrate, a metal layer (130) over the silicide layer, a solder interface layer (140) over the metal layer, and a cap layer (150) over the solder interface layer. The thinned silicon substrate is no thicker than approximately 500 micrometers. The silicide layer is formed using a rapid thermal processing procedure that locally heats the interface between the metal layer and the silicon substrate but causes no more than negligible thermal impact to other areas of the silicon wafer.

Abstract: A semiconductor device provided with a silicon carbide semiconductor substrate, and an ohmic metal layer joined to one surface of the silicon carbide semiconductor substrate in an ohmic contact and composed of a metal material whose silicide formation free energy and carbide formation free energy respectively take negative values. The ohmic metal layer is composed of, for example, a metal material such as molybdenum, titanium, chromium, manganese, zirconium, tantalum, or tungsten.

Abstract: A method of manufacturing a vertical GaN-based LED comprises preparing an n-type GaN substrate; sequentially forming an active layer and a p-type nitride semiconductor layer on the n-type GaN substrate through an epitaxial growth method; forming a p-electrode on the p-type nitride semiconductor layer; wet-etching the lower surface of the n-type GaN substrate so as to reduce the thickness of the n-type GaN substrate; forming a flat n-type bonding pad on the wet-etched lower surface of the n-type GaN substrate, the n-type bonding pad defining an n-electrode formation region; and forming an n-electrode on the n-type bonding pad.

Abstract: A semiconductor structure includes a semiconductor substrate, a semiconductor active region, a semiconductor contact layer, at least one metal migration semiconductor barrier layer, and a metal contact. The metal migration semiconductor barrier layer may be embedded within the semiconductor contact layer. Furthermore, the metal migration semiconductor barrier layer may be located underneath or above and in intimate contact with the semiconductor contact layer. The metal migration semiconductor barrier layer and the semiconductor contact layer form a contact structure that prevents metals from migrating from the metal contact into the semiconductor active layer during long-term exposure to high temperatures.

Abstract: A depletion mode (D-mode) field effect transistor (FET) is monolithically integrated with an enhancement mode (E-mode) FET in a multi-layer structure. The multi-layer structure includes a channel layer overlaid by a barrier layer overlaid by an ohmic contact layer. Source and drain contacts of the D-mode and E-mode FETs are coupled to the ohmic contact layer. A gate contact of the D-mode and E-mode FETs is coupled to the barrier layer. An amorphized region is provided beneath the E-mode gate contact within the barrier layer. The amorphized region forms a buried E-mode Schottky contact with the barrier layer. An alternative embodiment couples the gate contact of the D-mode transistor to a first layer that overlies the barrier layer, and provides a similar D-mode amorphized region within the first layer.

Abstract: A Schottky barrier silicon carbide device has a Re Schottky metal contact. The Re contact 27 is thicker than 250 Angstroms and may be between 2000 and 4000 Angstroms. A termination structure is provided by ion milling an annular region around the Schottky contact.

Abstract: A semiconductor device includes: a semiconductor layer made of a group-III nitride semiconductor and having a first surface and a second surface opposed to the first surface; a Schottky electrode formed on the first surface of the semiconductor layer; and an ohmic electrode electrically connected to the second surface of the semiconductor layer. The semiconductor layer has, in at least the upper portion thereof, highly-resistive regions selectively formed to have a high resistance.

Abstract: A field effect transistor configured for use in high power applications and a method for its fabrication is disclosed. The field effect transistor is formed of III-V materials and is configured to have a breakdown voltage that is advantageous for high power applications. The field effect transistor is so configured by determining the operating voltage and the desired breakdown voltage for that operating voltage. A peak electric field is then identified that is associated with the operating voltage and desired breakdown voltage. The device is then configured to exhibit the identified peak electric field at that operating voltage. The device is so configured by selecting device features that control the electrical potential in the device drift region is achieved. These features include the use of an overlapping gate or field plate in conjunction with a barrier layer overlying the device channel, or a p-type pocket formed in a region of single-crystal III-V material formed under the device channel.